Features _äìÉ`çêÉ
RJjìäíáãÉÇá~=cä~ëÜ
Fully Qualified
Bluetooth v2.1 + EDR Specification System
Best-in-class Bluetooth Radio with 5dBm
Transmit Power and -90dBm Receive Sensitivity
64MIPS Kalimba DSP Co-processor
16-bit Internal Stereo CODEC -95dB SNR for
DAC
Low-power 1.5V Operation, 1.8V to 3.6V I/O
Integrated 1.5V and 1.8V Linear Regulators
Integrated Switched-mode Regulator
Integrated Battery Charger
USB, I
2
C and UART with Dual Port Bypass Mode
to 4Mbits/s
8Mbit Internal Flash Memory
Multi-Configurable I
2
S, PCM or SPDIF Interface
Enhanced Audibility and Noise Cancellation
7 x 7 x 1.3mm, 0.5mm Pitch 120-ball LFBGA
Support for IEEE 802.11 Co-existence
RoHS Compliant
Single Chip Bluetooth® v2.1 + EDR
System
Production Information
BC57H687C
Issue 2
General Description
_äìÉ`çêÉ
RJjìäíáãÉÇá~=cä~ëÜ is a single-chip radio and
baseband IC for Bluetooth v2.1 + EDR specification
systems.
BlueCore5‑Multimedia Flash contains 8Mbit internal
Flash memory, which makes it one of the most
powerful and flexible Bluetoooth audio solutions with
the smallest PCB footprint on the market today. When
used with CSR's Bluetooth stack, it provides a fully
compliant Bluetooth v2.1 + EDR specification for data
and voice.
2.4
GHz
Radio
I
/
O
XTAL
RF IN
RF OUT
FLASH
RAM
Baseband
DSP
MCU
Kalimba DSP
SPI
UART/USB
PIO
Audio In/Out
PCM / I
2
S / SPDIF
Figure: System Architecture
Applications
Bluetooth-enabled Automotive Wireless
Gateways
High-quality Stereo Wireless Headsets
High-quality Mono Headsets
Hands-free Car Kits
Wireless Speakers
VOIP Handsets
Analogue and USB Multimedia Dongles
BlueCore5‑Multimedia Flash contains the Kalimba
DSP co-processor with double the MIPS and double
the memory of BlueCore3-Multimedia, supporting
enhanced audio applications.
BlueCore5‑Multimedia Flash is designed to reduce the
number of external components required which
ensures production costs are minimised.
The device incorporates auto-calibration and
built-in
self-test
(BIST) routines to simplify development, type
approval and production test.
To improve the performance of both Bluetooth and
IEEE 802.11b/g co-located systems a wide range of
co-existence features are available including a variety
of hardware signalling: basic activity signalling, Intel
WCS activity and channel signalling.
For radio performance over temperature and
additional information refer to the
BlueCore
®
5‑Multimedia Flash Performance
Specification
CS-113071-DSP2
Production Information
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© Cambridge Silicon Radio Limited 2007-2008
Page 1 of 101
_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
Document History
Revision Date Change Reason
Issue 1 10 AUG 07 Original Publication of document.
Issue 2 18 APR 08 Advance Information to Production Information
Device diagram, example application schematic and package dimensions update.
Stereo CODEC and Power Control and Regulation updates.
Power consumption figures added plus modification to RF_BIAS electrical characteristics.
Software section update.
Send feedback on this document to Comments@csr.com
Document History
CS-113071-DSP2
Production Information
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© Cambridge Silicon Radio Limited 2007-2008
Page 2 of 101
_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
Status Information
The status of this Data Sheet is Production Information.
CSR Product Data Sheets progress according to the following format:
Advance Information
Information for designers concerning CSR product in development. All values specified are the target values of the
design. Minimum and maximum values specified are only given as guidance to the final specification limits and must
not be considered as the final values.
All detailed specifications including pinouts and electrical specifications may be changed by CSR without notice.
Pre-Production Information
Pinout and mechanical dimension specifications finalised. All values specified are the target values of the design.
Minimum and maximum values specified are only given as guidance to the final specification limits and must not be
considered as the final values.
All electrical specifications may be changed by CSR without notice.
Production Information
Final Data Sheet including the guaranteed minimum and maximum limits for the electrical specifications.
Production Data Sheets supersede all previous document versions.
ESD Precautions
BlueCore5‑Multimedia Flash is classified as a JESD22-A114 class 2 product. Apply ESD static handling precautions
during manufacturing.
Life Support Policy and Use in Safety-Critical Applications
CSR's products are not authorised for use in life-support or safety-critical applications. Use in such applications is
done at the sole discretion of the customer. CSR will not warrant the use of its devices in such applications.
RoHS Compliance
BlueCore5‑Multimedia Flash devices meet the requirements of Directive 2002/95/EC of the European Parliament
and of the Council on the Restriction of Hazardous Substance (RoHS).
Trademarks, Patents and Licenses
Unless otherwise stated, words and logos marked with
or
®
are trademarks registered or owned by CSR plc or its
affiliates. Bluetooth
®
and the Bluetooth logos are trademarks owned by Bluetooth SIG, Inc. and licensed to CSR.
Other products, services and names used in this document may have been trademarked by their respective owners.
The publication of this information does not imply that any license is granted under any patent or other rights owned
by CSR plc.
CSR reserves the right to make technical changes to its products as part of its development programme.
While every care has been taken to ensure the accuracy of the contents of this document, CSR cannot accept
responsibility for any errors.
Status Information
CS-113071-DSP2
Production Information
This material is subject to CSR's non-disclosure agreement
© Cambridge Silicon Radio Limited 2007-2008
Page 3 of 101
_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
Contents
1 Device Details ................................................................................................................................................. 9
2 Device Diagram ............................................................................................................................................ 10
3 Package Information ..................................................................................................................................... 11
3.1 Pinout Diagram .................................................................................................................................... 11
3.2 BlueCore5‑Multimedia Flash Device Terminal Functions .................................................................... 12
3.3 Package Dimensions ........................................................................................................................... 18
3.4 PCB Design and Assembly Considerations ......................................................................................... 19
3.5 Typical Solder Reflow Profile ............................................................................................................... 19
4 Bluetooth Modem .......................................................................................................................................... 20
4.1 RF Ports ............................................................................................................................................... 20
4.1.1 RF_N and RF_P ..................................................................................................................... 20
4.2 RF Receiver ......................................................................................................................................... 20
4.2.1 Low Noise Amplifier ............................................................................................................... 20
4.2.2 RSSI Analogue to Digital Converter ....................................................................................... 20
4.3 RF Transmitter ..................................................................................................................................... 21
4.3.1 IQ Modulator .......................................................................................................................... 21
4.3.2 Power Amplifier ...................................................................................................................... 21
4.3.3 Transmit RF Power Control for Class 1 Applications (TX_PWR) ........................................... 21
4.4 Bluetooth Radio Synthesiser ............................................................................................................... 22
4.5 Baseband ............................................................................................................................................. 22
4.5.1 Burst Mode Controller ............................................................................................................ 22
4.5.2 Physical Layer Hardware Engine ........................................................................................... 22
4.6 Basic Rate Modem .............................................................................................................................. 22
4.7 Enhanced Data Rate Modem .............................................................................................................. 23
4.7.1 Enhanced Data Rate π/4 DQPSK .......................................................................................... 23
4.7.2 Enhanced Data Rate 8DPSK ................................................................................................. 24
5 Clock Generation .......................................................................................................................................... 26
5.1 Clock Architecture ................................................................................................................................ 26
5.2 Input Frequencies and PS Key Settings .............................................................................................. 26
5.3 External Reference Clock .................................................................................................................... 27
5.3.1 Input (XTAL_IN) ..................................................................................................................... 27
5.3.2 XTAL_IN Impedance in External Mode .................................................................................. 27
5.3.3 Clock Start-up Delay .............................................................................................................. 27
5.3.4 Clock Timing Accuracy ........................................................................................................... 27
5.4 Crystal Oscillator (XTAL_IN, XTAL_OUT) ........................................................................................... 28
5.4.1 Load Capacitance .................................................................................................................. 29
5.4.2 Frequency Trim ...................................................................................................................... 29
5.4.3 Transconductance Driver Model ............................................................................................ 30
5.4.4 Negative Resistance Model ................................................................................................... 30
5.4.5 Crystal PS Key Settings ......................................................................................................... 30
6 Bluetooth Stack Microcontroller .................................................................................................................... 31
6.1 TCXO Enable OR Function ................................................................................................................. 31
6.2 Programmable I/O (PIO) Parallel Ports ............................................................................................... 31
6.3 WLAN Coexistence Interface ............................................................................................................... 32
7 Kalimba DSP ................................................................................................................................................ 33
8 Memory Interface and Management ............................................................................................................. 34
8.1 Memory Management Unit .................................................................................................................. 34
8.2 System RAM ........................................................................................................................................ 34
8.3 Kalimba DSP RAM .............................................................................................................................. 34
8.4 Internal Flash Memory (8Mbit) ............................................................................................................. 34
Contents
CS-113071-DSP2
Production Information
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© Cambridge Silicon Radio Limited 2007-2008
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_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
8.4.1 Flash Specification ................................................................................................................. 34
9 Serial Interfaces ............................................................................................................................................ 35
9.1 UART Interface .................................................................................................................................... 35
9.1.1 UART Configuration While Reset is Active ............................................................................ 36
9.1.2 UART Bypass Mode ............................................................................................................... 37
9.1.3 Current Consumption in UART Bypass Mode ........................................................................ 37
9.2 USB Interface ...................................................................................................................................... 37
9.2.1 USB Data Connections .......................................................................................................... 37
9.2.2 USB Pull-up Resistor ............................................................................................................. 38
9.2.3 USB Power Supply ................................................................................................................. 38
9.2.4 Self-powered Mode ................................................................................................................ 38
9.2.5 Bus-powered Mode ................................................................................................................ 39
9.2.6 Suspend Current .................................................................................................................... 39
9.2.7 Detach and Wake_Up Signalling ............................................................................................ 40
9.2.8 USB Driver ............................................................................................................................. 40
9.2.9 USB 2.0 Compliance .............................................................................................................. 40
9.3 Serial Peripheral Interface ................................................................................................................... 40
9.3.1 Instruction Cycle ..................................................................................................................... 41
9.3.2 Writing to the Device .............................................................................................................. 41
9.3.3 Reading from the Device ........................................................................................................ 41
9.3.4 Multi-slave Operation ............................................................................................................. 42
9.4 I
2
C Interface ......................................................................................................................................... 42
9.4.1 Software I
2
C Interface ............................................................................................................ 42
9.4.2 Bit-serialiser Interface ............................................................................................................ 42
10 Audio Interface .............................................................................................................................................. 43
10.1 Audio Input and Output ........................................................................................................................ 43
10.2 Stereo Audio CODEC Interface ........................................................................................................... 44
10.2.1 Stereo Audio CODEC Block Diagram .................................................................................... 44
10.2.2 Stereo CODEC Set-up ........................................................................................................... 44
10.2.3 ADC ........................................................................................................................................ 45
10.2.4 ADC Sample Rate Selection .................................................................................................. 45
10.2.5 ADC Digital Gain .................................................................................................................... 45
10.2.6 ADC Analogue Gain ............................................................................................................... 46
10.2.7 DAC ........................................................................................................................................ 46
10.2.8 DAC Sample Rate Selection .................................................................................................. 46
10.2.9 DAC Digital Gain .................................................................................................................... 46
10.2.10 DAC Analogue Gain ............................................................................................................... 48
10.2.11 Microphone Input ................................................................................................................... 49
10.2.12 Line Input ............................................................................................................................... 51
10.2.13 Output Stage .......................................................................................................................... 53
10.2.14 Mono Operation ..................................................................................................................... 53
10.2.15 Side Tone ............................................................................................................................... 53
10.2.16 Integrated Digital Filter ........................................................................................................... 53
10.3 PCM Interface ...................................................................................................................................... 54
10.3.1 PCM Interface Master/Slave .................................................................................................. 55
10.3.2 Long Frame Sync ................................................................................................................... 55
10.3.3 Short Frame Sync .................................................................................................................. 56
10.3.4 Multi-slot Operation ................................................................................................................ 56
10.3.5 GCI Interface .......................................................................................................................... 57
10.3.6 Slots and Sample Formats ..................................................................................................... 58
10.3.7 Additional Features ................................................................................................................ 58
10.3.8 PCM Timing Information ........................................................................................................ 59
10.3.9 PCM_CLK and PCM_SYNC Generation ................................................................................ 63
Contents
CS-113071-DSP2
Production Information
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_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
10.3.10 PCM Configuration ................................................................................................................. 63
10.4 Digital Audio Interface (I²S) .................................................................................................................. 64
11 Power Control and Regulation ...................................................................................................................... 69
11.1 Power Sequencing ............................................................................................................................... 69
11.2 External Voltage Source ...................................................................................................................... 70
11.3 Switch-mode Regulator ....................................................................................................................... 70
11.4 High-voltage Linear Regulator ............................................................................................................. 70
11.5 Low-voltage Linear Regulator .............................................................................................................. 70
11.6 Low-voltage Audio Linear Regulator .................................................................................................... 71
11.7 Voltage Regulator Enable Pins ............................................................................................................ 71
11.8 Battery Charger ................................................................................................................................... 71
11.9 LED Drivers ......................................................................................................................................... 73
11.10Reset (RST#) ....................................................................................................................................... 74
11.10.1 Digital Pin States on Reset .................................................................................................... 74
11.10.2 Status after Reset .................................................................................................................. 75
12 Example Application Schematic ................................................................................................................... 76
13 Electrical Characteristics .............................................................................................................................. 77
13.1 Absolute Maximum Ratings ................................................................................................................. 77
13.2 Recommended Operating Conditions .................................................................................................. 77
13.3 Input/Output Terminal Characteristics ................................................................................................. 78
13.3.1 High-voltage Linear Regulator ............................................................................................... 78
13.3.2 Low-voltage Linear Regulator ................................................................................................ 79
13.3.3 Low-voltage Linear Audio Regulator ...................................................................................... 80
13.3.4 Reset ...................................................................................................................................... 81
13.3.5 Regulator Enable ................................................................................................................... 81
13.3.6 Switch-mode Regulator .......................................................................................................... 82
13.3.7 Battery Charger ...................................................................................................................... 83
13.3.8 Digital Terminals .................................................................................................................... 85
13.3.9 LED Driver Pads .................................................................................................................... 86
13.3.10 USB ........................................................................................................................................ 86
13.3.11 Auxiliary ADC ......................................................................................................................... 87
13.3.12 Auxiliary DAC ......................................................................................................................... 87
13.3.13 Clocks .................................................................................................................................... 88
13.3.14 Stereo CODEC: Analogue to Digital Converter ...................................................................... 89
13.3.15 Stereo CODEC: Digital to Analogue Converter ...................................................................... 90
14 Power Consumption ..................................................................................................................................... 91
14.1 Kalimba DSP and CODEC Typical Average Current Consumption .................................................... 93
14.2 Typical Peak Current at 20°C .............................................................................................................. 93
14.3 Conditions ............................................................................................................................................ 93
15 RoHS Statement with a List of Banned Materials ......................................................................................... 94
15.1 RoHS Statement .................................................................................................................................. 94
15.1.1 List of Banned Materials ......................................................................................................... 94
16 CSR Bluetooth Software Stack ..................................................................................................................... 95
16.1 BlueCore HCI Stack ............................................................................................................................ 95
16.1.1 Key Features of the HCI Stack: Standard Bluetooth Functionality ......................................... 95
16.1.2 Key Features of the HCI Stack: Extra Functionality ............................................................... 97
16.2 Host-Side Software .............................................................................................................................. 97
16.3 eXtension ............................................................................................................................................. 97
17 Ordering Information ..................................................................................................................................... 98
17.1 Tape and Reel Information .................................................................................................................. 98
17.2 Moisture Sensitivity Level (MSL) ......................................................................................................... 98
18 Document References .................................................................................................................................. 99
Terms and Definitions .......................................................................................................................................... 100
Contents
CS-113071-DSP2
Production Information
This material is subject to CSR's non-disclosure agreement
© Cambridge Silicon Radio Limited 2007-2008
Page 6 of 101
_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
List of Figures
Figure 2.1 BlueCore5‑Multimedia Flash Device Diagram ................................................................................ 10
Figure 3.1 BlueCore5‑Multimedia Flash Device Pinout .................................................................................... 11
Figure 3.2 BlueCore5‑Multimedia Flash 120-ball LFBGA Package Dimensions ............................................. 18
Figure 4.1 Simplified Circuit RF_N and RF_P .................................................................................................. 20
Figure 4.2 Internal Power Ramping .................................................................................................................. 21
Figure 4.3 Basic Rate and Enhanced Data Rate Packet Structure .................................................................. 23
Figure 4.4 π/4 DQPSK Constellation Pattern ................................................................................................... 24
Figure 4.5 8DPSK Constellation Pattern .......................................................................................................... 25
Figure 5.1 Clock Architecture ........................................................................................................................... 26
Figure 5.2 TCXO Clock Accuracy .................................................................................................................... 28
Figure 5.3 Crystal Driver Circuit ....................................................................................................................... 28
Figure 5.4 Crystal Equivalent Circuit ................................................................................................................ 28
Figure 6.1 Example TCXO Enable OR Function .............................................................................................. 31
Figure 7.1 Kalimba DSP Interface to Internal Functions .................................................................................. 33
Figure 9.1 Universal Asynchronous Receiver .................................................................................................. 35
Figure 9.2 Break Signal .................................................................................................................................... 36
Figure 9.3 UART Bypass Architecture ............................................................................................................. 37
Figure 9.4 USB Connections for Self-Powered Mode ...................................................................................... 38
Figure 9.5 USB Connections for Bus-Powered Mode ...................................................................................... 39
Figure 9.6 USB_DETACH and USB_WAKE_UP Signal ................................................................................... 40
Figure 9.7 SPI Write Operation ........................................................................................................................ 41
Figure 9.8 SPI Read Operation ........................................................................................................................ 42
Figure 9.9 Example EEPROM Connection ...................................................................................................... 42
Figure 10.1 Audio Interface ................................................................................................................................ 43
Figure 10.2 Stereo CODEC Audio Input and Output Stages ............................................................................. 44
Figure 10.3 ADC Analogue Amplifier Block Diagram ......................................................................................... 46
Figure 10.4 Microphone Biasing (Single Channel Shown) ................................................................................. 49
Figure 10.5 Differential Input (Single Channel Shown) ...................................................................................... 51
Figure 10.6 Single-Ended Input (Single Channel Shown) .................................................................................. 52
Figure 10.7 Speaker Output (Single Channel Shown) ....................................................................................... 53
Figure 10.8 PCM Interface Master ..................................................................................................................... 55
Figure 10.9 PCM Interface Slave ....................................................................................................................... 55
Figure 10.10 Long Frame Sync (Shown with 8-bit Companded Sample) ............................................................ 56
Figure 10.11 Short Frame Sync (Shown with 16-bit Sample) .............................................................................. 56
Figure 10.12 Multi-slot Operation with Two Slots and 8-bit Companded Samples .............................................. 56
Figure 10.13 GCI Interface ................................................................................................................................... 57
Figure 10.14 16-Bit Slot Length and Sample Formats ......................................................................................... 58
Figure 10.15 PCM Master Timing Long Frame Sync ........................................................................................... 60
Figure 10.16 PCM Master Timing Short Frame Sync .......................................................................................... 60
Figure 10.17 PCM Slave Timing Long Frame Sync ............................................................................................. 61
Figure 10.18 PCM Slave Timing Short Frame Sync ............................................................................................ 62
Figure 10.19 Digital Audio Interface Modes ......................................................................................................... 66
Figure 10.20 Digital Audio Interface Slave Timing ............................................................................................... 67
Figure 10.21 Digital Audio Interface Master Timing ............................................................................................. 68
Figure 11.1 Voltage Regulator Configuration ..................................................................................................... 69
Figure 11.2 LED Equivalent Circuit .................................................................................................................... 73
Figure 12.1 Example Application Schematic for BlueCore5‑Multimedia Flash .................................................. 76
Figure 16.1 BlueCore HCI Stack ........................................................................................................................ 95
Contents
CS-113071-DSP2
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© Cambridge Silicon Radio Limited 2007-2008
Page 7 of 101
_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
List of Tables
Table 4.1 TXRX_PIO_CONTROL Values ........................................................................................................ 22
Table 4.2 Data Rate Schemes ......................................................................................................................... 23
Table 4.3 2-Bits Determine Phase Shift Between Consecutive Symbols ......................................................... 24
Table 4.4 3-Bits Determine Phase Shift Between Consecutive Symbols ......................................................... 25
Table 5.1 PS Key Values for CDMA/3G Phone TCXO .................................................................................... 26
Table 5.2 External Clock Specifications ........................................................................................................... 27
Table 5.3 Crystal Specification ......................................................................................................................... 28
Table 8.1 Internal Flash Device Specifications ................................................................................................ 34
Table 9.1 Possible UART Settings ................................................................................................................... 35
Table 9.2 Standard Baud Rates ....................................................................................................................... 36
Table 9.3 USB Interface Component Values ................................................................................................... 39
Table 9.4 Instruction Cycle for an SPI Transaction .......................................................................................... 41
Table 10.1 Alternative Functions of the Digital Audio Bus Interface on the PCM Interface ............................... 43
Table 10.2 ADC Digital Gain Rate Selection ...................................................................................................... 45
Table 10.3 DAC Digital Gain Rate Selection ...................................................................................................... 47
Table 10.4 DAC Analogue Gain Rate Selection ................................................................................................. 48
Table 10.5 Voltage Output Steps ....................................................................................................................... 50
Table 10.6 Current Output Steps ....................................................................................................................... 51
Table 10.7 PCM Master Timing .......................................................................................................................... 59
Table 10.8 PCM Slave Timing ............................................................................................................................ 61
Table 10.9 PSKEY_PCM_LOW_JITTER_CONFIG Description ......................................................................... 63
Table 10.10 PSKEY_PCM_CONFIG32 Description ............................................................................................. 63
Table 10.11 Alternative Functions of the Digital Audio Bus Interface on the PCM Interface ............................... 65
Table 10.12 PSKEY_DIGITAL_AUDIO_CONFIG ................................................................................................. 65
Table 10.13 Digital Audio Interface Slave Timing ................................................................................................ 67
Table 10.14 Digital Audio Interface Master Timing .............................................................................................. 68
Table 11.1 BlueCore5‑Multimedia Flash Voltage Regulator Enable Pins .......................................................... 71
Table 11.2 Pin States on Reset .......................................................................................................................... 74
List of Equations
Equation 4.1 Output Voltage with Load Current I ................................................................................................. 21
Equation 4.2 Output Voltage with No Load Current ............................................................................................. 21
Equation 5.1 Load Capacitance ........................................................................................................................... 29
Equation 5.2 Trim Capacitance ............................................................................................................................ 29
Equation 5.3 Frequency Trim ............................................................................................................................... 29
Equation 5.4 Pullability ......................................................................................................................................... 29
Equation 5.5 Transconductance Required for Oscillation .................................................................................... 30
Equation 5.6 Equivalent Negative Resistance ..................................................................................................... 30
Equation 9.1 Baud Rate ....................................................................................................................................... 36
Equation 10.1IIR Filter Transfer Function, H(z) ..................................................................................................... 54
Equation 10.2 IIR Filter plus DC Blocking Transfer Function, H
DC
(z) .................................................................... 54
Equation 10.3 PCM_CLK Frequency When Being Generated Using the Internal 48MHz Clock ........................... 63
Equation 10.4PCM_SYNC Frequency Relative to PCM_CLK ............................................................................... 63
Equation 11.1LED Current .................................................................................................................................... 73
Equation 11.2LED PAD Voltage ............................................................................................................................ 73
Contents
CS-113071-DSP2
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_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
1 Device Details
Radio
Common TX/RX terminal simplifies external
matching; eliminates external antenna switch
BIST minimises production test time
Bluetooth v2.1 + EDR specification compliant
Transmitter
5dBm RF transmit power with level control from on-
chip 6-bit DAC over a dynamic range >30dB
Class 2 and Class 3 support without the need for an
external power amplifier or TX/RX switch
Receiver
Receiver sensitivity of -90dBm
Integrated channel filters
Digital demodulator for improved sensitivity and co-
channel rejection
Real-time digitised RSSI available on HCI interface
Fast AGC for enhanced dynamic range
Synthesiser
Fully integrated synthesiser requires no external
VCO, varactor diode, resonator or loop filter
Compatible with crystals 16MHz to 26MHz or an
external clock 12MHz to 52MHz
Accepts 14.40, 15.36, 16.2, 16.8, 19.2, 19.44,
19.68, 19.8 and 38.4MHz TCXO frequencies for
GSM and CDMA devices with sinusoidal or logic
level signals
Baseband and Software
8Mbit internal Flash
48Kbyte internal RAM, allows full-speed data
transfer, mixed voice/data and full piconet support
Logic for forward error correction, header error
control, access code correlation, CRC,
demodulation, encryption bit stream generation,
whitening and transmit pulse shaping
Transcoders for A-law, μ-law and linear voice from
host and A-law, μ-law and CVSD voice over air
Physical Interfaces
Serial peripheral interface
(SPI) with clock speeds
up to 64MHz in Master mode
(1)
and 32MHz in Slave
mode
I
2
C master compatible interface
UART interface with programmable data rate up to
3Mbits/s with an optional bypass mode
USB v2.0 interface
Bi-directional serial programmable audio interface
supporting PCM, I
2
S and SPDIF formats
Two LED drivers with faders
Kalimba DSP
Very low power Kalimba DSP co-processor,
64MIPS, 24-bit fixed point core
SBC decode takes approximately 4mW power
consumption while streaming music
Single-cycle MAC; 24 x 24-bit multiply and 56-bit
accumulator
32-bit instruction word, dual 24-bit data memory
6K x 32-bit program RAM, 16K x 24-bit + 12K x 24-
bit data RAM
64-word x 32-bit program memory cache when
executing from Flash
Stereo Audio CODEC
16-bit internal stereo CODEC
Dual ADC and DAC for stereo audio
Integrated amplifiers for driving 16Ω speakers; no
need for external components
Support for single-ended speaker termination and
line output
Integrated low-noise microphone bias
ADC sample rates are 8, 11.025, 16, 22.05, 32 and
44.1kHz
DAC sample rates are 8, 11.025, 12, 16, 22.05, 24,
32, 44.1 and 48kHz
Auxiliary Features
User space on processor for customer applications
Crystal oscillator with built-in digital trimming
Power management includes digital shutdown and
wake-up commands with an integrated low-power
oscillator for ultra-low power Park/Sniff/Hold mode
Clock request output to control external clock
On-chip regulators: 1.5V output from 1.8V to 2.7V
input and 1.8V output from 2.7V to 4.5V input
On-chip high-efficiency switched-mode regulator;
1.8V output from 2.7V to 4.4V input
Power-on-reset cell detects low supply voltage
10-bit ADC and 8-bit DAC available to applications
On-chip charger for lithium ion/polymer batteries
Bluetooth Stack
CSR's Bluetooth Protocol Stack runs on the on-chip
MCU in a variety of configurations:
Standard HCI (UART or USB)
Audio CODEC and echo-noise suppression or
customer-specific algorithms running on the DSP
Package Option
LFBGA 120-ball, 7 x 7 x 1.3mm, 0.5mm pitch
(1)
Requires firmware support
Device Details
CS-113071-DSP2
Production Information
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© Cambridge Silicon Radio Limited 2007-2008
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_äìÉ`çêÉRJjìäíáãÉÇá~=cä~ëÜ Product Data Sheet
2 Device Diagram
Bluetooth Modem
Switch Mode
Regulator
Clock
Generation
AUX
DAC
Power Control and Regulation
SENSE
Audio Low
Voltage Regulator
OUT
IN EN
VREGIN_AUDIO
VDD_AUDIO
VREGENABLE_L
VREGIN_L
VREGIN_H
VREGOUT_H
EN
VREGENABLE_H
BAT_N
Battery Charger
OUT
IN
BAT_P
VDD_CHG
AUX_DAC
Basic Rate
Modem
Enhanced
Rate Modem
Radio Control
Baseband
XTAL_OUT
XTAL_IN
LO_REF
VDD_RADIO
VDD_LO
LED[0]
VDD_PADS
VSS_DIG
VSS_ANA
VSS_AUDIO
SUBS
VDD_MEM
RST#
TEST_EN
High Voltage
Linear Regulator
OUT
IN EN
SENSE
VDD_SMP_CORE
Low Voltage
Linear Regulator
OUT SENSE
SENSE
VDD_CORE
IN EN
VDD_ANA
LX
I
2
C Bus available on any PIO
pins, default configuration shown
VSS_LO
VSS_RADIO
Memory Management Unit
Microcontroller
MCU
Interrupt
Controller
Timers
System RAM
DSP
Kalimba DSP
Interrupt
Controller
Timers
Data Memory
DM2
Program
Memory PM
Data Memory
DM1
PCM /I
2
S
Interface SPDIF Stereo Audio
Interface
Audio Interfaces
SPKR_A_P
SPKR_A_N
SPKR_B_N
SPKR_B_P
MIC_BIAS
MIC_A_P
MIC_A_N
MIC_B_N
MIC_B_P
AU_REF
PCM_CLK
PCM_SYNC
PCM_OUT
PCM_IN
Serial Interfaces
USB UART
UART_TX
UART_RX
UART_CTS
UART_RTS
USB_DP
USB_DN
VDD_USB
I
2
C Interface
PIO[7]
PIO[8]
PIO[6]
SPI
Interface
SPI_CS#
SPI_MISO
SPI_MOSI
SPI_CLK
SCL
SDA
Internal Flash Memory Interface
8Mbit Flash
Programmable I/O
LED Driver AIO GPIO
LED[1]
AIO[0]
AIO[1]
PIO[5:0]
VSS_PIO
VDD_PIO
PIO[15:9]
Bluetooth
v2.1 Radio
RF_P
RF_N
Figure 2.1: BlueCore5‑Multimedia Flash Device Diagram
Device Diagram
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3 Package Information
3.1 Pinout Diagram
K3
L4
J3
D12
E12E11
F12 F13F11
G12 G13G11
H12 H13H11
J11
K11
L9 L10 L11L8L7L6L5
B8
C1 C2
B3B2B1
A3
C3
E3
D3
C4 C5 C6
D13
F3
E1
B5
A4
B4
A5
G3
J1
G1
F1
C8
K1
A8
D11
A1
D1
H3H1
A2
G2
F2
E2 E13
L1 L2
D2
B6 B7
A6 A7
K2
L3
H2
J2
C7
A
B
C
D
E
F
G
H
J
K
L
12345678 9 10 11
A9 A10 A11
B9 B10 B11
C9 C10 C11
A12 A13
B12 B13
C12 C13
12 13
J12 J13
K12 K13
L12 L13
M4 M9 M10 M11M8M7M6M5M1 M2 M3 M12 M13
N4 N9 N10 N11N8N7N6N5N1 N2 N3 N12 N13
M
N
Top View
Figure 3.1: BlueCore5‑Multimedia Flash Device Pinout
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3.2 BlueCore5‑Multimedia Flash Device Terminal Functions
Radio Ball Pad Type Supply Domain Description
RF_P H1 RF VDD_RADIO Transmitter output/switched
receiver input
RF_N J1 RF VDD_RADIO Complement of RF_P
AUX_DAC H3 Analogue VDD_PIO Voltage DAC
Synthesiser and
Oscillator Ball Pad Type Supply Domain Description
XTAL_IN N1 Analogue VDD_ANA For crystal or external clock input
XTAL_OUT N2 Analogue VDD_ANA Drive for crystal
LO_REF N5 Analogue VDD_ANA Reference voltage to decouple the
synthesiser
UART and USB Ball Pad Type Supply Domain Description
UART_TX L13
Bi-directional CMOS
output, tri-state, with
weak internal pull-up
VDD_USB UART data output
UART_RX M12
CMOS input with
weak internal pull-
down
VDD_USB UART data input
UART_RTS M11
Bi-directional CMOS
output, tri-state, with
weak internal pull-up
VDD_USB UART request to send, active low
UART_CTS M13
CMOS input with
weak internal pull-
down
VDD_USB UART clear to send, active low
USB_DP N13 Bi-directional VDD_USB USB data plus with selectable
internal 1.5kΩ pull-up resistor
USB_DN N12 Bi-directional VDD_USB USB data minus
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PCM Interface Ball Pad Type Supply Domain Description
PCM_OUT F11
CMOS output, tri-
state, with weak
internal pull-down
VDD_PADS Synchronous data output
PCM_IN F13
CMOS input, with
weak internal pull-
down
VDD_PADS Synchronous data input
PCM_SYNC G11
Bi-directional with
weak internal pull-
down
VDD_PADS Synchronous data sync
PCM_CLK H11
Bi-directional with
weak internal pull-
down
VDD_PADS Synchronous data clock
SPI Interface Ball Pad Type Supply Domain Description
SPI_MISO E12
CMOS output, tri-
state, with weak
internal pull-down
VDD_PADS SPI data output
SPI_MOSI F12
CMOS input, with
weak internal pull-
down
VDD_PADS SPI data input
SPI_CS# E13 Input with weak
internal pull-up VDD_PADS Chip select for Serial Peripheral
Interface (SPI), active low
SPI_CLK E11 Input with weak
internal pull-down VDD_PADS SPI clock
PIO Port Ball Pad Type Supply Domain Description
PIO[0]/RXEN E3
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PIO Programmable input/output line
(external RXEN)
PIO[1]/TXEN F3
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PIO Programmable input/output line
(external TXEN)
PIO[2] E2
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PIO Programmable input/output line
PIO[3] D3
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PIO Programmable input/output line
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PIO Port Ball Pad Type Supply Domain Description
PIO[4] H12
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[5] J11
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[6] M8
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[7] H13
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[8] J12
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[9] L12
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[10] L10
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[11] M10
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
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PIO Port Ball Pad Type Supply Domain Description
PIO[12] K12
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[13] M9
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[14] L9
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
PIO[15] N9
Bi-directional with
programmable
strength internal pull-
up/down
VDD_PADS Programmable input/output line
AIO[0] N6 Bi-directional VDD_ANA Analogue programmable input/
output line
AIO[1] M5 Bi-directional VDD_ANA Analogue programmable input/
output line
Test and Debug Ball Pad Type Supply Domain Description
RST# G13 CMOS input with
weak internal pull-up VDD_PADS
Reset if low. Input debounced so
must be low for >5ms to cause a
reset
TEST_EN G12
CMOS input with
strong internal pull-
down
VDD_PADS For test purposes only (leave
unconnected)
CODEC Ball Pad Type Supply Domain Description
MIC_A_P B2 Analogue VDD_AUDIO Microphone input positive, left
MIC_A_N B1 Analogue VDD_AUDIO Microphone input negative, left
MIC_B_P A2 Analogue VDD_AUDIO Microphone input positve, right
MIC_B_N A1 Analogue VDD_AUDIO Microphone input negative, right
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CODEC Ball Pad Type Supply Domain Description
SPKR_A_P D1 Analogue VDD_AUDIO Speaker output positive, left
SPKR_A_N D2 Analogue VDD_AUDIO Speaker output negative, left
SPKR_B_P A3 Analogue VDD_AUDIO Speaker output positive, right
SPKR_B_N B3 Analogue VDD_AUDIO Speaker output negative, right
MIC_BIAS A5 Analogue VDD_AUDIO Microphone bias
AU_REF_DCPL C1 Analogue VDD_AUDIO Decoupling of audio reference (for
high-quality audio)
LED Drivers Ball Pad Type Supply Domain Description
LED[1] C8 Open drain output See Section 11.9 LED driver
LED[0] D11 Open drain output See Section 11.9 LED driver
Power Supplies and
Control Ball Pad Type Description
VREGENABLE_L M3 Analogue
Take high to enable both low-
voltage regulator and audio low-
voltage regulator
VREGENABLE_H C7 Analogue
Take high to enable high-voltage
linear regulator and switch-mode
regulator
VREGIN_L M2 Regulator input Low-voltage linear regulator input
for non-audio core circuitry
VREGIN_AUDIO A4 Regulator input Audio low-voltage linear regulator
input
VREGIN_H B12, C12 Regulator input High-voltage linear regulator input
VREGOUT_H D12, D13 Supply High-voltage linear regulator output
LX A11, B11
Switched-mode
power regulator
output
Switched-mode power regulator
output
VDD_USB N10 VDD Positive supply for UART and USB
ports
VDD_PIO E1 VDD Positive supply for PIO and AUX
DAC
VDD_PADS K13 VDD Positive supply for all other digital
input/output ports
VDD_CORE C13, J13 VDD Positive supply for internal digital
circuitry, 1.5V
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Power Supplies and
Control Ball Pad Type Description
VDD_RADIO K1 VDD/Low-voltage
regulator sense Positive supply for RF circuitry, 1.5V
VDD_LO L1 VDD Positive supply for local oscillator
circuitry, 1.5V
VDD_ANA M1 VDD/Low-voltage
regulator output
Positive supply output for analogue
circuitry and 1.5V regulated output
(from low-voltage regulator)
VDD_AUDIO B4 VDD Positive supply for audio, 1.5V
BAT_P A12, A13 Battery terminal +ve
Lithium ion/polymer battery positive
terminal. Battery charger output and
input to switch-mode regulator
VDD_CHG B8, B9, C9 Charger input Lithium ion/polymer battery charger
input
VDD_SMP_CORE B13 VDD Positive supply for switch mode
control circuitry
VDD_MEM A8, N11 VDD Positive supply for internal Flash
memory
VSS_DIG G3, C6, N7, A9, A10, C11,
K11, L11 VSS Ground connection for internal
digital circuitry
VSS_RADIO F2, G2, H2, J2 VSS Ground connections for RF circuitry
VSS_LO L2, L3 VSS Ground connections for local
oscillator
VSS_ANA N3, N4 VSS Ground connections for analogue
circuitry
VSS_AUDIO C2, C3, C4 VSS Ground connection for audio
BAT_N B10, C10 Battery terminal -ve
Lithium ion/polymer battery
negative terminal. Ground
connection for switch-mode
regulator.
SUBS
K2, J3, K3, L4, M4, B5, C5,
L5, A6, B6, L6, M6, A7, B7,
L7, M7, L8, N8
VSS
Connection to internal die substrate.
Connect to lowest possible
potential.
Unconnected Terminals Ball Description
N/C F1, G1 Leave unconnected
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3.3 Package Dimensions
Figure 3.2: BlueCore5‑Multimedia Flash 120-ball LFBGA Package Dimensions
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3.4 PCB Design and Assembly Considerations
This section lists recommendations to achieve maximum board-level reliability of the 7 x 7 x 1.3mm LFBGA 120-ball
package:
Non solder mask defined
(NSMD) lands (that is, lands smaller than the solder mask aperture) are preferred
because of the greater accuracy of the metal definition process compared to the solder mask process. With
solder mask defined pads, the overlap of the solder mask on the land creates a step in the solder at the
land interface, which can cause stress concentration and act as a point for crack initiation.
Ideally, via-in-pad technology should be used to achieve truly NSMD lands. Where this is not possible, a
maximum of one trace connected to each land is preferred and this trace should be as thin as possible –
taking into consideration its current carrying and the
radio frequency
(RF) requirements.
35µm thick (1oz) copper lands are recommended rather than 17µm thick (0.5oz). This results in a greater
standoff which has been proven to provide greater reliability during thermal cycling.
Land diameter should be the same as that on the package to achieve optimum reliability.
Solder paste is preferred to flux during the assembly process because this adds to the final volume of solder
in the joint, increasing its reliability.
Where a nickel gold plating finish is used, the gold thickness should be kept below 0.5µm to prevent brittle
gold/tin intermetallics forming in the solder.
3.5 Typical Solder Reflow Profile
See
Typical Solder Reflow Profile for Lead-free Device
for information.
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4 Bluetooth Modem
4.1 RF Ports
4.1.1 RF_N and RF_P
RF_N and RF_P form a complementary balanced pair and are available for both transmit and receive. On transmit
their outputs are combined using a balun into the single-ended output required for the antenna. Similarly, on receive
their input signals are combined internally.
Both terminals present similar complex impedances that require matching networks between them and the balun.
Viewed from the chip, the outputs can each be modelled as an ideal current source in parallel with a lossy capacitor.
An equivalent series inductance can represent the package parasitics.
BlueCore
+
_
PA
+
_
LNA
RF
Switch
RF
Switch
RF_N
RF_P
Figure 4.1: Simplified Circuit RF_N and RF_P
The DC level must be set at VDD_RADIO.
4.2 RF Receiver
The receiver features a near-zero
intermediate frequency
(IF) architecture that allows the channel filters to be
integrated onto the die. Sufficient out-of-band blocking specification at the
low-noise amplifier
(LNA) input allows the
receiver to be used in close proximity to
Global System for Mobile Communications
(GSM) and
Wideband Code
Division Multiple Access
(W-CDMA) cellular phone transmitters without being desensitised. The use of a digital
Frequency Shift Keying (FSK) discriminator means that no discriminator tank is needed and its excellent performance
in the presence of noise allows BlueCore5‑Multimedia Flash to exceed the Bluetooth requirements for co-channel
and adjacent channel rejection.
For EDR, the demodulator contains an ADC which digitises the IF received signal. This information is then passed
to the EDR modem.
4.2.1 Low Noise Amplifier
The LNA operates in differential mode and takes its input from the shared RF port.
4.2.2 RSSI Analogue to Digital Converter
The
Analogue to Digital Converter
(ADC) implements fast
Automatic Gain Control
(AGC). The ADC samples the
received signal strength indicator
(RSSI) voltage on a slot-by-slot basis. The front-end LNA gain is changed
according to the measured RSSI value, keeping the first mixer input signal within a limited range. This improves the
dynamic range of the receiver, improving performance in interference limited environments.
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4.3 RF Transmitter
4.3.1 IQ Modulator
The transmitter features a direct IQ modulator to minimise the frequency drift during a transmit timeslot, which results
in a controlled modulation index. Digital baseband transmit circuitry provides the required spectral shaping.
4.3.2 Power Amplifier
The internal
Power Amplifier
(PA) has a maximum output power that allows BlueCore5‑Multimedia Flash to be used
in Class 2 and Class 3 radios without an external RF PA.
4.3.3 Transmit RF Power Control for Class 1 Applications (TX_PWR)
An 8-bit voltage DAC (AUX_DAC) controls the amplification level of the external PA for Class 1 operation. The DAC
output is derived from the on-chip band gap and is virtually independent of temperature and supply voltage. Equation
4.1 and Equation 4.2 show the the output voltage:
V
DAC
=MIN
((
3.7V ×
EXT_PA_GAIN
255
−0.008×I
)
, PIOSupply 0.008 × I
)
Equation 4.1: Output Voltage with Load Current I
or
V
DAC
=MIN
((
3.7V × EXT_PA_GAIN
255
)
,PIOSupply
)
Equation 4.2: Output Voltage with No Load Current
Note:
PIOSupply = VDD_PIO
BlueCore5‑Multimedia Flash enables the external PA only when transmitting. Before transmitting, the chip normally
ramps up the power to the internal PA, then it ramps it down again afterwards. However, if a suitable external PA is
used, it may be possible to ramp the power externally by driving the TX_PWR pin on the PA from AUX_DAC.
TX Power
Modulation
t
carrier
Figure 4.2: Internal Power Ramping
The
Persistent Store Key
(PS Key) PSKEY_TX_GAINRAMP (
0x1d
), is used to control the delay (in units of μs)
between the end of the transmit power ramp and the start of modulation.
PS Key TXRX_PIO_CONTROL (0x209) controls external RF components such as a switch, an external PA or an
external LNA. PIO[0], PIO[1] and the AUX_DAC can be used for this purpose, as Table 4.1 shows.
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TXRX_PIO_CONTROL Value PIO and AUX_DAC Use
0PIO[0], PIO[1], and AUX_DAC not used to control RF. Power ramping is
internal.
1PIO[0] is high during RX, PIO[1] is high during TX. AUX_DAC not used.
Power ramping is internal.
2PIO[0] is high during RX, PIO[1] is high during TX. AUX_DAC used to set
gain of external PA. Power ramping is external.
3PIO[0] is low during RX, PIO[1] is low during TX. AUX_DAC used to set gain
of external PA. Power ramping is external.
4PIO[0] is high during RX, PIO[1] is high during TX. AUX_DAC used to set
gain of external PA. Power ramping is internal.
Table 4.1: TXRX_PIO_CONTROL Values
4.4 Bluetooth Radio Synthesiser
The Bluetooth radio synthesiser is fully integrated onto the die with no requirement for an external
Voltage Controlled
Oscillator
(VCO) screening can, varactor tuning diodes, LC resonators or loop filter. The synthesiser is guaranteed
to lock in sufficient time across the guaranteed temperature range to meet the Bluetooth v2.1 + EDR specification.
4.5 Baseband
4.5.1 Burst Mode Controller
During transmission the
Burst Mode Controller
(BMC) constructs a packet from header information previously loaded
into memory-mapped registers by the software and payload data/voice taken from the appropriate ring buffer in the
RAM. During reception, the BMC stores the packet header in memory-mapped registers and the payload data in the
appropriate ring buffer in RAM. This architecture minimises the intervention required by the processor during
transmission and reception.
4.5.2 Physical Layer Hardware Engine
Dedicated logic performs the following:
Forward error correction
Header error control
Cyclic redundancy check
Encryption
Data whitening
Access code correlation
Audio transcoding
Firmware performs the following voice data translations and operations:
A-law/µ-law/linear voice data (from host)
A-law/µ-law/
Continuously Variable Slope Delta
(CVSD) (over the air)
Voice interpolation for lost packets
Rate mismatches
The hardware supports all optional and mandatory features of Bluetooth v2.1 + EDR specification including AFH
and eSCO.
4.6 Basic Rate Modem
The Basic Rate modem satisfies the basic data rate requirements of the Bluetooth v2.1 + EDR specification. The
basic rate was the standard data rate available on the Bluetooth v1.2 specification and below, it is based on
Gaussian
Frequency Shift Keying
(GFSK) modulation scheme.
The inclusion of the basic rate modem allows BlueCore5‑Multimedia Flash compatibility with earlier Bluetooth
products.
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The basic rate modem uses the RF Ports, Receiver, Transmitter and Synthesiser, alongside the baseband
components described in Section 4.5.
4.7 Enhanced Data Rate Modem
The
Enhanced Data Rate
(EDR) modem satisfies the requirements of the Bluetooth v2.1 + EDR specification. EDR
has been introduced to provide 2x and 3x data rates with minimal disruption to higher layers of the Bluetooth stack.
BlueCore5‑Multimedia Flash supports both the basic and enhanced data rates and is compliant with the
Bluetooth v2.1 + EDR specification.
At the baseband level, EDR utilises both the same 1.6kHz slot rate and the 1MHz symbol rate as defined for the
basic data rate. EDR differs in that each symbol in the payload portion of a packet represents 2 or 3-bits. This is
achieved using two new distinct modulation schemes. Table 4.2 and Figure 4.3 summarise these. Link Establishment
and management are unchanged and still use GFSK for both the header and payload portions of these packets.
The enhanced data rate modems uses the RF Ports, Receiver, Transmitter and Synthesiser, with the baseband
components described in Section 4.5.
Data Rate Scheme Bits Per Symbol Modulation
Basic Data Rate 1GFSK
EDR 2π/4 DQPSK
EDR 38DPSK (optional)
Table 4.2: Data Rate Schemes
Access Code
Access Code
Header
Header
Payload
Guard Sync Payload Trailer
B
as
i
c
R
ate
Enhanced Data Rate
/
4 DQPSK or 8DPSK
Figure 4.3: Basic Rate and Enhanced Data Rate Packet Structure
4.7.1 Enhanced Data Rate π/4 DQPSK
The 2x data rate for EDR uses a π/4-DQPSK. Each symbol represents 2-bits of information. Figure 4.4 shows the
constellation. It has two planes, each having four points. Although it seems there are eight possible phase states,
the encoding ensures that the trajectory of the modulation between symbols is restricted to the four states in the
other plane.
For a given starting point, each phase change between symbols is restricted to +3π/4, +π/4, -π/4 or -3π/4 radians
(+135°, +45°, -45° or -135°). For example, the arrows shown in Figure 4.4 represent trajectory to the four possible
states in the other plane. Table 4.3 shows the phase shift encoding of symbols.
There are two main advantages in using π/4 DQPSK modulation:
The scheme avoids the crossing of the origin (a +π or -π phase shift) and therefore minimises amplitude
variations in the envelope of the transmitted signal. This in turn allows the RF power amplifiers of the
transmitter to be operated closer to their compression point without introducing spectral distortions.
Consequently, the DC to RF efficiency is maximised.
The differential encoding also allows for the demodulation without the knowledge of an absolute value for
the phase of the RF carrier.
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0001
11 10
Figure 4.4: π/4 DQPSK Constellation Pattern
Bit Pattern Phase Shift
00 π/4
01 3π/4
11 -3π/4
10 -π/4
Table 4.3: 2-Bits Determine Phase Shift Between Consecutive Symbols
4.7.2 Enhanced Data Rate 8DPSK
The 3x data rate modulation uses eight phase differential phase shift keying (8DPSK). Each symbol in the payload
portion of the packet represents 3 baseband bits. Although it seems the 8DPSK is similar to π/4 DQPSK, the
differential phase shifts between symbols are now permissible between any of the eight possible phase states. This
reduces the separation between adjacent symbols on the constellation to π/4 (45°) and thereby reduces the noise
and interference immunity of the modulation scheme. Nevertheless, because each symbol now represents 3
baseband bits, the actual throughput of the data is 3x when compared with the basic rate packet.
Figure 4.5 shows the 8DPSK constellation and Table 4.4 shows the phase encoding.
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001010
111 100
000
011
110
101
Figure 4.5: 8DPSK Constellation Pattern
Bit Pattern Phase Shift
000 0
001 π/4
011 π/2
010 3π/4
110 π
111 -3π/4
101 -π/2
100 -π/4
Table 4.4: 3-Bits Determine Phase Shift Between Consecutive Symbols
Bluetooth Modem
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5 Clock Generation
BlueCore5‑Multimedia Flash requires a Bluetooth reference clock frequency of 12MHz to 52MHz from either an
externally connected crystal or from an external TCXO source.
All BlueCore5‑Multimedia Flash internal digital clocks are generated using a phase locked loop, which is locked to
the frequency of either the external 12MHz to 52MHz reference clock source or an internally generated watchdog
clock frequency of 1kHz.
The Bluetooth operation determines the use of the watchdog clock in low-power modes.
5.1 Clock Architecture
Bluetooth
Radio
Auxilliary
PLL
Digital
Circuitry
Reference Clock
Figure 5.1: Clock Architecture
5.2 Input Frequencies and PS Key Settings
BlueCore5‑Multimedia Flash should be configured to operate with the chosen reference frequency. Do this by setting
the PS Key ANA_FREQ (
0x01FE
) for all frequencies with an integer multiple of 250kHz. The input frequency default
setting in BlueCore5‑Multimedia Flash is 26MHz depending on the software build. Full details are in the software
release note for the specific build from www.csrsupport.com.
The following CDMA/3G phone TCXO frequencies are also catered for: 14.40, 15.36, 16.2, 16.8, 19.2, 19.44, 19.68,
19.8 and 38.4MHz. The value of the PS Key is a multiple of 1kHz, so 38.4MHz is selected by using a PS Key value
of 38400.
Reference Crystal Frequency (MHz) ANA_FREQ (
0x1fe
) (kHz)
14.40 14400
15.36 15360
16.20 16200
16.80 16800
19.20 19200
19.44 19440
19.68 19680
19.80 19800
38.40 38400
n x 0.25 n x 250
26.00 (default) 26000
Table 5.1: PS Key Values for CDMA/3G Phone TCXO
Clock Generation
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5.3 External Reference Clock
5.3.1 Input (XTAL_IN)
The external reference clock is applied to the BlueCore5‑Multimedia Flash XTAL_IN input.
BlueCore5‑Multimedia Flash is configured to accept the external reference clock at XTAL_IN by connecting
XTAL_OUT to ground. The external clock can be either a digital level square wave or sinusoidal, and this may be
directly coupled to XTAL_IN without the need for additional components. A digital level reference clock gives superior
noise immunity, as the high slew rate clock edges have lower voltage to phase conversion. If peaks of the reference
clock are either below VSS_ANA or above VDD_ANA, it must be driven through a DC blocking capacitor
(approximately 33pF) connected to XTAL_IN.
The external reference clock signal should meet the specifications outlined in Table 5.2.
Min Typ Max Unit
Frequency
(a)
12 26 52 MHz
Duty cycle 20:80 50:50 80:20
Edge Jitter (At Zero Crossing) - - 15 ps rms
Signal Level
AC coupled sinusoid 400 -VDD_ANA
(b)
mV pk-pk
DC coupled
digital
V
IL
-VSS_ANA
(c)
- V
V
IH
-VDD_ANA
(b)
(c)
- V
Table 5.2: External Clock Specifications
(a)
The frequency should be an integer multiple of 250kHz except for the CDMA/3G frequencies
(b)
VDD_ANA is 1.50V nominal
(c)
If driven via a DC blocking capacitor max amplitude is reduced to 750mV pk-pk for non 50:50 duty cycle
5.3.2 XTAL_IN Impedance in External Mode
The impedance of XTAL_IN does not change significantly between operating modes, typically 10fF. When
transitioning from Deep Sleep to an active state a spike of up to 1pC may be measured. For this reason CSR
recommends that a buffered clock input is used.
5.3.3 Clock Start-up Delay
BlueCore5‑Multimedia Flash hardware incorporates an automatic 5ms delay after the assertion of the system clock
request signal before running firmware. This is suitable for most applications using an external clock source.
However, there may be scenarios where the clock cannot be guaranteed to either exist or be stable after this period.
Under these conditions, BlueCore5‑Multimedia Flash firmware provides a software function that extends the system
clock request signal by a period stored in PSKEY_CLOCK_STARTUP_DELAY. This value is set in milliseconds from
1-31ms. Zero is the default entry for 5ms delay.
This PS Key allows the designer to optimise a system where clock latencies may be longer than 5ms while still
keeping the current consumption of BlueCore5‑Multimedia Flash as low as possible. BlueCore5‑Multimedia Flash
consumes about 2mA of current for the duration of PSKEY_CLOCK_STARTUP_DELAY before activating the
firmware.
5.3.4 Clock Timing Accuracy
As Figure 5.2 shows, the 250ppm timing accuracy on the external clock is required 2ms after the firmware begins
to run. This is to guarantee that the firmware can maintain timing accuracy in accordance with the
Bluetooth v2.1 + EDR specification. Radio activity may occur after 6ms after the firmware starts. Therefore, at this
point the timing accuracy of the external clock source must be within ±20ppm.
Clock Generation
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Clock Accuracy
0
20 ppm
+6
250 ppm
+2
1000 ppm
ms After Firmware
CLK_REQ
Firmware Activity
PSKEY_CLOCK_STARTUP_DELAY
Firmware Activity
Radio Activity
Figure 5.2: TCXO Clock Accuracy
5.4 Crystal Oscillator (XTAL_IN, XTAL_OUT)
BlueCore5‑Multimedia Flash contains a crystal driver circuit. This operates with an external crystal and capacitors
to form a Pierce oscillator. The external crystal is connected to pins XTAL_IN, XTAL_OUT.
-
g
m
C
trim
C
int
C
t2
C
t1
XTAL_IN
XTAL_OUT
Figure 5.3: Crystal Driver Circuit
Figure 5.4 shows an electrical equivalent circuit for a crystal. The crystal appears inductive near its resonant
frequency. It forms a resonant circuit with its load capacitors.
L
m
R
m
C
m
C
o
Figure 5.4: Crystal Equivalent Circuit
The resonant frequency may be trimmed with the crystal load capacitance. BlueCore5‑Multimedia Flash contains
variable internal capacitors to provide a fine trim.
Parameter Min Typ Max Unit
Frequency 16 26 26 MHz
Initial Tolerance -±25 -ppm
Pullability -±20 -ppm/pF
Transconductance 2.0 - - mS
Table 5.3: Crystal Specification
Clock Generation
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The BlueCore5‑Multimedia Flash driver circuit is a transconductance amplifier. A voltage at XTAL_IN generates a
current at XTAL_OUT. The value of transconductance is variable and may be set for optimum performance.
5.4.1 Load Capacitance
For resonance at the correct frequency the crystal should be loaded with its specified load capacitance, which is
defined for the crystal. This is the total capacitance across the crystal viewed from its terminals.
BlueCore5‑Multimedia Flash provides some of this load with the capacitors C
trim
and C
int
. The remainder should be
from the external capacitors labelled C
t1
and C
t2
. C
t1
should be three times the value of C
t2
for best noise
performance. This maximises the signal swing, hence slew rate at XTAL_IN (to which all on-chip clocks are referred).
Crystal load capacitance, C
l
is calculated with Equation 5.1:
C
l
=C
int
+
(Ct2 +C
trim )Ct1
Ct2 +C
trim +C
t1
Equation 5.1: Load Capacitance
Note:
C
trim
= 3.4pF nominal (mid-range setting)
C
int
= 1.5pF
C
int
does not include the crystal internal self capacitance; it is the driver self capacitance.
5.4.2 Frequency Trim
BlueCore5‑Multimedia Flash enables frequency adjustments to be made. This feature is typically used to remove
initial tolerance frequency errors associated with the crystal. Frequency trim is achieved by adjusting the crystal load
capacitance with an on-chip trim capacitor, C
trim
. The value of C
trim
is set by a 6-bit word in the PS Key ANA_FTRIM
(
0x1f6
). Its value is calculated as follows:
C
trim
= 125fF × PSKEY_ANA_FTRIM
Equation 5.2: Trim Capacitance
The C
trim
capacitor is connected between XTAL_IN and ground. When viewed from the crystal terminals, the
combination of the tank capacitors and the trim capacitor presents a load across the terminals of the crystal which
varies in steps of typically 125fF for each least significant bit increment of ANA_FTRIM.
Equation 5.3 describes the frequency trim.
Δ(Fx)
Fx
= pullability × 0.110 ×
(
Ct1
Ct1 +C
t2 +C
trim
)
(ppm / LSB)
Equation 5.3: Frequency Trim
Note:
F
x
= crystal frequency
Pullability is a crystal parameter with units of ppm/pF.
Total trim range is 0 to 63.
If not specified, the pullability of a crystal may be calculated from its motional capacitance with Equation 5.4.
()
() ()
2
0I
I
m
X
X
CC
C2
C
F
F
+
=
Equation 5.4: Pullability
Clock Generation
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Note:
C
0
= Crystal self capacitance (shunt capacitance)
C
m
= Crystal motional capacitance (series branch capacitance in crystal model). See Figure 5.4.
It is a Bluetooth requirement that the frequency is always within ±20ppm. The trim range should be sufficient to
pull the crystal within ±5ppm of the exact frequency. This leaves a margin of ±15ppm for frequency drift with
ageing and temperature. A crystal with an ageing and temperature drift specification of better than ±15ppm is
required.
5.4.3 Transconductance Driver Model
The crystal and its load capacitors should be viewed as a transimpedance element, whereby a current applied to
one terminal generates a voltage at the other. The transconductance amplifier in BlueCore5‑Multimedia Flash uses
the voltage at its input, XTAL_IN, to generate a current at its output, XTAL_OUT. Therefore, the circuit will oscillate
if the transconductance, transimpedance product is greater than unity. For sufficient oscillation amplitude, the
product should be greater than three. The transconductance required for oscillation is defined by the relationship
shown in Equation 5.5.
gm>3
(F
x)2Rm
((
C0+C
int
)(
Ct1 +C
t2 +C
trim
)
+C
t1
(
Ct2 +C
trim
))
Ct1 (Ct2 +C
trim )
Equation 5.5: Transconductance Required for Oscillation
BlueCore5‑Multimedia Flash guarantees a transconductance value of at least 2mA/V at maximum drive level.
Note:
More drive strength is required for higher frequency crystals, higher loss crystals (larger R
m
) or higher
capacitance loading.
Optimum drive level is attained when the level at XTAL_IN is approximately 1V pk-pk. The drive level is
determined by the crystal driver transconductance.
5.4.4 Negative Resistance Model
An alternative representation of the crystal and its load capacitors is a frequency dependent resistive element. The
driver amplifier may be considered as a circuit that provides negative resistance. For oscillation, the value of the
negative resistance must be greater than that of the crystal circuit equivalent resistance. Although the
BlueCore5‑Multimedia Flash crystal driver circuit is based on a transimpedance amplifier, an equivalent negative
resistance can be calculated for it using Equation 5.6.
R
neg
>
Ct1 (Ct2 +C
trim )
gm(F
x)2
(
C0+C
int
)((
Ct1 +C
t2 +C
trim
)
+C
t1
(
Ct2 +C
trim
))
2
Equation 5.6: Equivalent Negative Resistance
This formula shows the negative resistance of the BlueCore5‑Multimedia Flash driver as a function of its drive
strength.
The value of the driver negative resistance may be easily measured by placing an additional resistance in series
with the crystal. The maximum value of this resistor (oscillation occurs) is the equivalent negative resistance of the
oscillator.
5.4.5 Crystal PS Key Settings
The BlueCore5‑Multimedia Flash firmware automatically controls the drive level on the crystal circuit to achieve
optimum input swing. The PS Key PSKEY_XTAL_TARGET_AMPLITUDE (
0x24b
) is used by the firmware to servo
the required amplitude of crystal oscillation. Refer to the software build release note for a detailed description.
BlueCore5‑Multimedia Flash should be configured to operate with the chosen reference frequency.
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6 Bluetooth Stack Microcontroller
The
microcontroller unit
(MCU), interrupt controller and event timer run the Bluetooth software stack and control the
Bluetooth radio and host interfaces. A 16-bit
reduced instruction set computer
(RISC) microcontroller is used for low
power consumption and efficient use of memory.
6.1 TCXO Enable OR Function
An OR function exists for clock enable signals from a host controller and BlueCore5‑Multimedia Flash where either
device can turn on the clock without having to wake up the other device, see Figure 6.1. PIO[3] can be used as the
host clock enable input and PIO[2] can be used as the OR output with the TCXO enable signal from
BlueCore5‑Multimedia Flash.
Note:
To turn on the clock, the clock enable signal on PIO[3] must be high.
BlueCore System
GSM System
TCXO
VDD
Enable
CLK IN
CLK IN
CLK REQ IN/
PIO[3]
CLK REQ OUT/
PIO[2]
CLK REQ OUT
Figure 6.1: Example TCXO Enable OR Function
On reset and up to the time the PIO has been configured, PIO[2] is tri-state. Therefore, the developer must ensure
that the circuitry connected to this pin is pulled via a 470kΩ resistor to the appropriate power rail. This ensures that
the TCXO is oscillating at start up.
6.2 Programmable I/O (PIO) Parallel Ports
18 lines of programmable bi-directional
input/outputs
(I/O) are provided.
Note:
PIO[15:4] are powered from VDD_PADS and PIO[3:0] are powered from VDD_PIO. AIO[0:1] are powered from
VDD_ANA.
Any of the PIO lines can be configured as interrupt request lines or as wake-up lines from sleep modes. PIO[6] or
PIO[2] can be configured as a request line for an external clock source. Using PSKEY_CLOCK_REQUEST_ENABLE
(
0x246
), this terminal can be configured to be low when BlueCore5‑Multimedia Flash is in Deep Sleep and high
when a clock is required.
Note:
CSR cannot guarantee that the PIO assignments remain as described. Refer to the relevant software release
note for the implementation of these PIO lines, as they are firmware build-specific.
BlueCore5‑Multimedia Flash has two general-purpose analogue interface pins, AIO[0:1], used to access internal
circuitry and control signals. Auxiliary functions available on the analogue interface include a 10-bit ADC and a 8-bit
DAC. Signals selectable on this interface include the band gap reference voltage and a variety of clock signals: 64,
Bluetooth Stack Microcontroller
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48, 32, 24, 16, 12, 8, 6 and 2MHz (outputted from AIO[0] only) and the XTAL and XTAL/2 clock frequency (outputted
from AIO[0] and AIO[1]). When used with analogue signals the voltage range is constrained by the analogue supply
voltage. When configured to drive out digital level signals (clocks) generated from within the analogue part of the
device, the output voltage level is determined by VDD_ANA.
6.3 WLAN Coexistence Interface
Dedicated hardware is provided to implement a variety of coexistence schemes. Channel skipping AFH, priority
signalling, channel signalling and host passing of channel instructions are all supported. The features are configured
in firmware.
For more information see
Bluetooth and IEEE 802.11 b/g Coexistence Solutions Overview
.
Bluetooth Stack Microcontroller
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7 Kalimba DSP
The Kalimba DSP is an open platform Kalimba DSP allowing signal processing functions to be performed on over
air data or CODEC data in order to enhance audio applications. The Kalimba DSP interfaces to other functional
blocks within BlueCore5‑Multimedia Flash as shown in Figure 7.1.
DSP RAMs
Memory
Management Unit
MCU Register Interface (including Debug)
Kalimba DSP Core
DM2
(12K x 24-bit)
DM1
(16K x 24-bit)
PM
(6K x 32-bit)
Instruction Decode
Program Flow DEBUG
Data Memory
Interface
Address
Generators
ALU
Clock Select PIO
Internal Control Registers
MMU Interface
Interrupt Controller
Timer
MCU Window
Flash Window
DSP MMU Port
DSP Data Memory 2 Interface (DM2)
DSP Data Memory 1 Interface (DM1)
DSP Program Memory Interface (PM)
Registers
Programmable Clock = 64MHz
PIO In/Out
IRQ to Subsystem
IRQ from Subsystem
1µs Timer Clock
DSP Program Control
DSP, MCU and Flash Window Control
Figure 7.1: Kalimba DSP Interface to Internal Functions
The key features of the DSP include:
64MIPS performance, 24-bit fixed point DSP Core
Single cycle MAC of 24 x 24-bit multiply and 56-bit accumulate
32-bit instruction word
Separate program memory and dual data memory, allowing an ALU operation and up to two memory
accesses in a single cycle
Zero overhead looping
Zero overhead circular buffer indexing
Single cycle barrel shifter with up to 56-bit input and 24-bit output
Multiple cycle divide (performed in the background)
Bit reversed addressing
Orthogonal instruction set
Low overhead interrupt
Kalimba DSP
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8 Memory Interface and Management
8.1 Memory Management Unit
The
Memory Management Unit
(MMU) provides a number of dynamically allocated ring buffers that hold the data
that is in transit between the host, the air or the Kalimba DSP. The dynamic allocation of memory ensures efficient
use of the available
Random Access Memory
(RAM) and is performed by a hardware MMU to minimise the
overheads on the processor during data/voice transfers.
8.2 System RAM
48Kbyte of on-chip RAM supports the RISC MCU and is shared between the ring buffers used to hold voice/data
for each active connection and the general-purpose memory required by the Bluetooth stack.
8.3 Kalimba DSP RAM
Additional on-chip RAM is provided to support the Kalimba DSP:
16K x 24-bit for data memory 1 (DM1)
12K x 24-bit for data memory 2 (DM2)
6K x 32-bit for program memory (PM)
Note:
The DSP can also execute directly from internal Flash, using a 64-instruction on-chip cache.
8.4 Internal Flash Memory (8Mbit)
8Mbit of internal Flash memory is available on the BlueCore5‑Multimedia Flash. The internal Flash memory is
provided for system firmware and the Kalimba DSP co-processor code implementation.
The internal Flash memory provides 8Mbit of internal code and data storage. This storage is used to store
BlueCore5‑Multimedia Flash settings and program code, and Kalimba DSP co-processor code and data.
8.4.1 Flash Specification
The flash device used with BlueCore5‑Multimedia Flash meets the following criteria:
Parameter Value
Data width 16-bit
Capacity 8Mbit
Access time 70ns
Table 8.1: Internal Flash Device Specifications
Memory Interface and Management
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9 Serial Interfaces
9.1 UART Interface
This is a standard UART interface for communicating with other serial devices.
BlueCore5‑Multimedia Flash UART interface provides a simple mechanism for communicating with other serial
devices using the RS232 protocol.
UART_TX
UART_RX
UART_RTS
UART_CTS
Figure 9.1: Universal Asynchronous Receiver
Four signals implement the UART function, as shown in Figure 9.1. When BlueCore5‑Multimedia Flash is connected
to another digital device, UART_RX and UART_TX transfer data between the two devices. The remaining two
signals, UART_CTS and UART_RTS, can be used to implement RS232 hardware flow control where both are active
low indicators.
UART configuration parameters, such as baud rate and packet format, are set using BlueCore5‑Multimedia Flash
firmware.
Note:
To communicate with the UART at its maximum data rate using a standard PC, an accelerated serial port adapter
card is required for the PC.
Parameter Possible Values
Baud rate Minimum
1200 baud (≤2%Error)
9600 baud (≤1%Error)
Maximum 4Mbaud (≤1%Error)
Flow control RTS/CTS or None
Parity None, Odd or Even
Number of stop bits 1 or 2
Bits per byte 8
Table 9.1: Possible UART Settings
The UART interface can reset BlueCore5‑Multimedia Flash on reception of a break signal. A break is identified by
a continuous logic low (0V) on the UART_RX terminal, as shown in Figure 9.2. If t
BRK
is longer than the value, defined
by the PS Key PSKEY_HOSTIO_UART_RESET_TIMEOUT, (
0x1a4
), a reset occurs. This feature allows a host to
initialise the system to a known state. Also, BlueCore5‑Multimedia Flash can emit a break character that may be
used to wake the host.
Serial Interfaces
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UART RX
tBRK
Figure 9.2: Break Signal
Note:
The DFU boot loader must be loaded into the Flash device before the UART or USB interfaces can be used.
This initial flash programming can be done via the SPI.
Table 9.2 shows a list of commonly used baud rates and their associated values for the PS Key
PSKEY_UART_BAUDRATE (
0x1be
). There is no requirement to use these standard values. Any baud rate within
the supported range can be set in the PS Key according to the formula in Equation 9.1.
Baud Rate = PSKEY_UART_BAUDRATE
0.004096
Equation 9.1: Baud Rate
Baud Rate
Persistent Store Value
Error
Hex Dec
1200 0x0005 51.73%
2400 0x000a 10 1.73%
4800 0x0014 20 1.73%
9600 0x0027 39 -0.82%
19200 0x004f 79 0.45%
38400 0x009d 157 -0.18%
57600 0x00ec 236 0.03%
76800 0x013b 315 0.14%
115200 0x01d8 472 0.03%
230400 0x03b0 944 0.03%
460800 0x075f 1887 -0.02%
921600 0x0ebf 3775 0.00%
1382400 0x161e 5662 -0.01%
1843200 0x1d7e 7550 0.00%
2764800 0x2c3d 11325 0.00%
3686400 0x3afb 15099 0.00%
Table 9.2: Standard Baud Rates
9.1.1 UART Configuration While Reset is Active
The UART interface for BlueCore5‑Multimedia Flash is tri-state while the chip is being held in reset. This allows the
user to daisy chain devices onto the physical UART bus. The constraint on this method is that any devices connected
to this bus must tri-state when BlueCore5‑Multimedia Flash reset is de-asserted and the firmware begins to run.
Serial Interfaces
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9.1.2 UART Bypass Mode
Host Processor UART Bypass Another Device
RST#
UART
RXD
CTS
Test Interface
RTS
UART_RX
UART_CTS
UART_RTS
UART_TX PIO4
PIO5
PIO6
PIO7
TXD
TX
RTS
CTS
RX
Figure 9.3: UART Bypass Architecture
Alternatively, for devices that do not tri-state the UART bus, the UART bypass mode on BlueCore5‑Multimedia Flash
can be used. The default state of BlueCore5‑Multimedia Flash after reset is de-asserted; this is for the host UART
bus to be connected to the BlueCore5‑Multimedia Flash UART, thereby allowing communication to
BlueCore5‑Multimedia Flash via the UART. All UART bypass mode connections are implemented using CMOS
technology and have signalling levels of 0V and VDD_PADS.
To apply the UART bypass mode, a BCCMD command is issued to BlueCore5‑Multimedia Flash. Upon this issue,
it switches the bypass to PIO[7:4] as Figure 9.3 shows. When the bypass mode has been invoked,
BlueCore5‑Multimedia Flash enters the Deep Sleep state indefinitely.
To re-establish communication with BlueCore5‑Multimedia Flash, the chip must be reset so that the default
configuration takes effect.
It is important for the host to ensure a clean Bluetooth disconnection of any active links before the bypass mode is
invoked. Therefore, it is not possible to have active Bluetooth links while operating the bypass mode.
9.1.3 Current Consumption in UART Bypass Mode
The current consumption for a device in UART bypass mode is equal to the values quoted for a device in standby
mode.
9.2 USB Interface
This is a full speed (12Mbits/s) Universal Serial Bus (USB) interface for communicating with other compatible digital
devices. BlueCore5‑Multimedia Flash acts as a USB peripheral, responding to requests from a master host controller
such as a PC.
The USB interface is capable of driving a USB cable directly. No external USB transceiver is required. The device
operates as a USB peripheral, responding to requests from a master host controller such as a PC. Both the OHCI
and the UHCI standards are supported.
Note:
The set of USB endpoints implemented can behave as specified in the USB section of the
Bluetooth v2.1 + EDR specification or alternatively can appear as a set of endpoints appropriate to USB audio
devices such as speakers.
As USB is a master/slave oriented system (in common with other USB peripherals), BlueCore5‑Multimedia Flash
only supports USB Slave operation.
9.2.1 USB Data Connections
The USB data lines emerge as pins USB_DP and USB_DN. These terminals are connected to the internal USB I/O
buffers of the BlueCore5‑Multimedia Flash, therefore, have a low output impedance. To match the connection to the
characteristic impedance of the USB cable, resistors must be placed in series with USB_DP/USB_DN and the cable.
Serial Interfaces
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9.2.2 USB Pull-up Resistor
BlueCore5‑Multimedia Flash features an internal USB pull-up resistor. This pulls the USB_DP pin weakly high when
BlueCore5‑Multimedia Flash is ready to enumerate. It signals to the PC that it is a full-speed (12-Mbits/s) USB device.
The USB internal pull-up is implemented as a current source, and is compliant with section 7.1.5 of the USB
specification v1.2. The internal pull-up pulls USB_DP high to at least 2.8V when loaded with a 15kΩ ± 5% pull-down
resistor (in the hub/host) when VDD_USB=3.1V. This presents a Thevenin resistance to the host of at least 900Ω.
Alternatively, an external 1.5kΩ pull-up resistor can be placed between a PIO line and D+ on the USB cable, see
Section 9.2.4. The firmware must be alerted to which mode is used by setting PS Key PSKEY_USB_PIO_PULLUP
appropriately. The default setting uses the internal pull-up resistor.
9.2.3 USB Power Supply
The USB specification dictates that the minimum output high voltage for USB data lines is 2.8V. To safely meet the
USB specification, the voltage on the VDD_USB supply terminals must be an absolute minimum of 3.1V. CSR
recommends 3.3V for optimal USB signal quality.
9.2.4 Self-powered Mode
In self-powered mode, the circuit is powered from its own power supply and not from the VBUS (5V) line of the USB
cable. It draws only a small leakage current (below 0.5mA) from VBUS on the USB cable. This is the easier mode
for which to design, as the design is not limited by the power that can be drawn from the USB hub or root port.
However, it requires that VBUS be connected to BlueCore5‑Multimedia Flash via a resistor network (R
vb1
and
R
vb2
), so BlueCore5‑Multimedia Flash can detect when VBUS is powered up. BlueCore5‑Multimedia Flash will not
pull USB_DP high when VBUS is off.
Self-powered USB designs (powered from a battery or PSU) must ensure that a PIO line is allocated for USB pull-
up purposes. A 1.5kΩ ±5% pull-up resistor between USB_DP and the selected PIO line should be fitted to the design.
Failure to fit this resistor may result in the design failing to be USB compliant in self-powered mode. The internal
pull-up in BlueCore5‑Multimedia Flash is only suitable for bus-powered USB devices, e.g. dongles.
D-
VBUS
D+
GND
R
s
R
s
R
vb1
R
vb2
1.5kΩ
5%
PIO
USB_DP
USB_DN
USB_ON
Figure 9.4: USB Connections for Self-Powered Mode
The terminal marked USB_ON can be any free PIO pin. The PIO pin selected must be registered by setting
PSKEY_USB_PIO_VBUS to the corresponding pin number.
Note:
For the self-powered mode described in this section to function correctly, the PIO terminals selected in Figure
9.4 must configured for 3.3V operation on the BlueCore5‑Multimedia Flash.
USB_ON is shared with BlueCore5‑Multimedia Flash PIO terminals.
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Identifier Value Function
R
s
27Ω nominal Impedance matching to USB cable
R
vb1
22kΩ ±5% VBUS ON sense divider
R
vb2
47kΩ ±5% VBUS ON sense divider
Table 9.3: USB Interface Component Values
9.2.5 Bus-powered Mode
In bus-powered mode, the application circuit draws its current from the 5V VBUS supply on the USB cable.
BlueCore5‑Multimedia Flash negotiates with the PC during the USB enumeration stage about how much current it
is allowed to consume.
For Class 2 Bluetooth applications, CSR recommends that the regulator used to derive 3.3V from VBUS is rated at
100mA average current and should be able to handle peaks of 120mA without foldback or limiting. In bus-powered
mode, BlueCore5‑Multimedia Flash requests 100mA during enumeration.
For Class 1 Bluetooth applications, the USB power descriptor should be altered to reflect the amount of power
required. This is accomplished by setting the PS Key PSKEY_USB_MAX_POWER (
0x2c6
). This is higher than for
a Class 2 application due to the extra current drawn by the Transmit RF PA.
When selecting a regulator, be aware that VBUS may go as low as 4.4V. The inrush current (when charging reservoir
and supply decoupling capacitors) is limited by the USB specification. See USB Specification v1.1, section 7.2.4.1.
Some applications may require soft start circuitry to limit inrush current if more than 10μF is present between VBUS
and GND.
The 5V VBUS line emerging from a PC is often electrically noisy. As well as regulation down to 3.3V and 1.8V,
applications should include careful filtering of the 5V line to attenuate noise that is above the voltage regulator
bandwidth. Excessive noise on the 1.8V supply to the analogue supply pins of BlueCore5‑Multimedia Flash results
in reduced receive sensitivity and a distorted RF transmit signal.
D-
VBUS
D+
GND
R
s
R
s
Voltage
Regulator
USB_DP
USB_DN
USB_ON
Figure 9.5: USB Connections for Bus-Powered Mode
9.2.6 Suspend Current
All USB devices must permit the USB controller to place them in a USB suspend mode. While in USB Suspend,
bus-powered devices must not draw more than 0.5mA from USB VBUS (self-powered devices may draw more than
0.5mA from their own supply). This current draw requirement prevents operation of the radio by bus-powered devices
during USB Suspend.
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The voltage regulator circuit itself should draw only a small quiescent current (typically less than 100μA) to ensure
adherence to the suspend current requirement of the USB specification. This is not normally a problem with modern
regulators. Ensure that external LEDs and/or amplifiers can be turned off by BlueCore5‑Multimedia Flash. The entire
circuit must be able to enter the suspend mode. Refer to separate CSR documentation for more details on USB
Suspend.
9.2.7 Detach and Wake_Up Signalling
BlueCore5‑Multimedia Flash can provide out-of-band signalling to a host controller by using the control lines called
USB_DETACH and USB_WAKE_UP. These are outside the USB specification (no wires exist for them inside the
USB cable), but can be useful when embedding BlueCore5‑Multimedia Flash into a circuit where no external USB
is visible to the user. Both control lines are shared with PIO pins and can be assigned to any PIO pin by setting the
PS Keys PSKEY_USB_PIO_DETACH and PSKEY_USB_PIO_WAKEUP to the selected PIO number.
USB_DETACH is an input which, when asserted high, causes BlueCore5‑Multimedia Flash to put USB_DN and
USB_DP in a high impedance state and turns off the pull-up resistor on DP. This detaches the device from the bus
and is logically equivalent to unplugging the device. When USB_DETACH is taken low, BlueCore5‑Multimedia Flash
will connect back to USB and await enumeration by the USB host.
USB_WAKE_UP is an active high output (used only when USB_DETACH is active) to wake up the host and allow
USB communication to recommence. It replaces the function of the software USB WAKE_UP message (which runs
over the USB cable) and cannot be sent while BlueCore5‑Multimedia Flash is effectively disconnected from the bus.
Disconnected
No max
10ms max10ms max
USB_DP
USB_DN
USB PULL-UP
Port_Impedance
USB_WAKE_UP
USB_DETACH
10ms max
Figure 9.6: USB_DETACH and USB_WAKE_UP Signal
9.2.8 USB Driver
A USB device driver is required to provide a software interface between BlueCore5‑Multimedia Flash and the
software running on the host computer. Suitable drivers are available from www.csrsupport.com.
9.2.9 USB 2.0 Compliance
BlueCore5‑Multimedia Flash is qualified to the USB specification v2.0, details of which are available from
www.usb.org. The specification contains valuable information on aspects such as PCB track impedance, supply
inrush current and product labelling.
BlueCore5‑Multimedia Flash is compatible with USB v2.0 host controllers; under these circumstances the two ends
agree the mutually acceptable rate of 12Mbits/s according to the USB v2.0 specification.
Although BlueCore5‑Multimedia Flash meets the USB specification, CSR cannot guarantee that an application circuit
designed around the chip is USB compliant. The choice of application circuit, component choice and PCB layout all
affect USB signal quality and electrical characteristics. The information in this document is intended as a guide and
should be read in association with the USB specification, with particular attention being given to Chapter 7.
Independent USB qualification must be sought before an application is deemed USB compliant and can display the
USB logo.
Terminals USB_DP and USB_DN adhere to the USB specification v2.0 (Chapter 7) electrical requirements.
9.3 Serial Peripheral Interface
The primary function of the SPI is for debug. BlueCore5‑Multimedia Flash uses a 16-bit data and 16-bit address SPI,
where transactions may occur when the internal processor is running or is stopped. This section details the interface
considerations for connection to BlueCore5‑Multimedia Flash .
Data may be written or read one word at a time, or the auto-increment feature is available for block access.
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9.3.1 Instruction Cycle
The BlueCore5‑Multimedia Flash is the slave and receives commands on SPI_MOSI and outputs data on SPI_MISO.
Table 9.4 shows the instruction cycle for an SPI transaction.
1Reset the SPI interface Hold SPI_CS# high for two SPI_CLK cycles
2Write the command word Take SPI_CS# low and clock in the 8-bit command
3Write the address Clock in the 16-bit address word
4Write or read data words Clock in or out 16-bit data word(s)
5Termination Take SPI_CS# high
Table 9.4: Instruction Cycle for an SPI Transaction
With the exception of reset, SPI_CS# must be held low during the transaction. Data on SPI_MOSI is clocked into
the BlueCore5‑Multimedia Flash on the rising edge of the clock line SPI_CLK. When reading,
BlueCore5‑Multimedia Flash replies to the master on SPI_MISO with the data changing on the falling edge of the
SPI_CLK. The master provides the clock on SPI_CLK. The transaction is terminated by taking SPI_CS# high.
Sending a command word and the address of a register for every time it is to be read or written is a significant
overhead, especially when large amounts of data are to be transferred. To overcome this
BlueCore5‑Multimedia Flash offers increased data transfer efficiency via an auto increment operation. To invoke
auto increment, SPI_CS# is kept low, which auto increments the address, while providing an extra 16 clock cycles
for each extra word to be written or read.
9.3.2 Writing to the Device
To write to BlueCore5‑Multimedia Flash, the 8-bit write command (00000010) is sent first (C[7:0]) followed by a 16-
bit address (A[15:0]). The next 16-bits (D[15:0]) clocked in on SPI_MOSI are written to the location set by the address
(A). Thereafter for each subsequent 16-bits clocked in, the address (A) is incremented and the data written to
consecutive locations until the transaction terminates when SPI_CS# is taken high.
SPI_CS#
SPI_CLK
SPI_MOSI
SPI_MISO
C7 C6 C1 C0 A15 A14 A1 A0 D15 D14 D1 D0 D15 D14 D1 D0 D15 D14 D1 D0 Don't Care
Processor
State
Address(A) Data(A) Data(A+1) etcWrite_Command
Reset
Processor
State MISO Not Defined During Write
End of Cycle
Figure 9.7: SPI Write Operation
9.3.3 Reading from the Device
Reading from BlueCore5‑Multimedia Flash is similar to writing to it. An 8-bit read command (00000011) is sent first
(C[7:0]), followed by the address of the location to be read (A[15:0]). BlueCore5‑Multimedia Flash then outputs on
SPI_MISO a check word during T[15:0] followed by the 16-bit contents of the addressed location during bits D[15:0].
The check word is composed of {command, address [15:8]}. The check word may be used to confirm a read operation
to a memory location. This overcomes the problems encountered with typical serial peripheral interface slaves,
whereby it is impossible to determine whether the data returned by a read operation is valid data or the result of the
slave device not responding.
If SPI_CS# is kept low, data from consecutive locations is read out on SPI_MISO for each subsequent 16 clocks,
until the transaction terminates when SPI_CS# is taken high.
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SPI_CS#
SPI_CLK
SPI_MOSI
SPI_MISO
C7 C6 C1 C0 A15 A14 A1 A0 Don't Care
T15 T14 T1 T0 D15 D14 D1 D0 D15 D14 D1 D0 D15 D14 D1 D0
Address(A) Check_Word Data(A) Data(A+1) etc
Reset
Read_Command
End of Cycle
Processor
State
Processor
State
MISO Not Defined During Address
Figure 9.8: SPI Read Operation
9.3.4 Multi-slave Operation
BlueCore5‑Multimedia Flash should not be connected in a multi-slave arrangement by simple parallel connection of
slave MISO lines. When BlueCore5‑Multimedia Flash is deselected (SPI_CS# = 1), the SPI_MISO line does not
float. Instead, BlueCore5‑Multimedia Flash outputs 0 if the processor is running or 1 if it is stopped.
9.4 I2C Interface
9.4.1 Software I
2
C Interface
PIO[6:8] can be used to form a Master I
2
C interface. The interface is formed using software to drive these lines.
Therefore it is suited only to relatively slow functions such as driving a dot matrix
liquid crystal display
(LCD),
keyboard scanner or EEPROM.
Serial EEPROM
(24AA32)
4
3
2
1
5
6
7
8
PIO[8]
PIO[7]
PIO[6]
VCC
WP
SCL
SDA
A0
A1
A2
GND
+1.8V
Decoupling
Capacitor
Figure 9.9: Example EEPROM Connection
9.4.2 Bit-serialiser Interface
In addition to the software I
2
C interface outlined in Section 9.4.1, the BlueCore5‑Multimedia Flash includes a
configurable hardware bit-serialiser interface. Any three PIOs can be used as a serial master interface by configuring
the hardware bit-serialiser. In the I
2
C master mode, the hardware bit-serialiser supports address, direction and ACK
handling, but does not support multi-master I
2
C bus systems. I
2
C slave mode is also not supported.
Note:
The I
2
C interface can be directly controlled by the MCU or the Kalimba DSP.
Suitable firmware is required to support the hardware bit-serialiser interface.
I
2
C and SPI are supported.
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10 Audio Interface
The audio interface circuit consists of:
Stereo audio CODEC
Dual audio inputs and outputs
A configurable PCM, I
2
S or SPDIF interface
Figure 10.1 shows the functional blocks of the interface. The CODEC supports stereo playback and recording of
audio signals at multiple sample rates with a resolution of 16-bit. The ADC and the DAC of the CODEC each contain
two independent channels. Any ADC or DAC channel can be run at its own independent sample rate.
Stereo CODEC
Memory
Management
Unit
MMU Voice Port
MCU Register Interface
Voice Port
Registers
PCM
Digital
Audio
Stereo
Audio
CODEC
Driver
PCM Interface
Left DAC
Right DAC
Right ADC
Left ADC
Figure 10.1: Audio Interface
The interface for the digital audio bus shares the same pins as the PCM CODEC interface described in Section
10.3 which means each of the audio buses are mutually exclusive in their usage. Table 10.1 lists these alternative
functions.
PCM Interface SPDIF Interface I
2
S Interface
PCM_OUT SPDIF_OUT SD_OUT
PCM_IN SPDIF_IN SD_IN
PCM_SYNC -WS
PCM_CLK -SCK
Table 10.1: Alternative Functions of the Digital Audio Bus Interface on the PCM Interface
10.1 Audio Input and Output
The audio input circuitry consists of a dual audio input that can be configured to be either single-ended or fully
differential and programmed for either microphone or line input. It has an analogue and digital programmable gain
stage for optimisation of different microphones.
The audio output circuitry consists of a dual differential class A-B output stage.
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10.2 Stereo Audio CODEC Interface
The main features of the interface are:
Stereo and mono analogue input for voice band and audio band
Stereo and mono analogue output for voice band and audio band
Support for stereo digital audio bus standards such as I
2
S
Support for IEC-60958 standard stereo digital audio bus standards, e.g. S/PDIF and AES3/EBU
Support for PCM interfaces including PCM master CODECs that require an external system clock
Important Note:
To avoid any confusion regarding stereo operation this data sheet explicitly states which is the left and right
channel for audio input and output. With respect to software and any registers, channel 0 or channel A represents
the left channel and channel 1 or channel B represents the right channel for both input and output.
10.2.1 Stereo Audio CODEC Block Diagram
Digital
Circuitry
Output
Amplifier
Input
Amplifier
LP Filter
MIC_A_P
SPKR_A_P
Output
Amplifier
Input
Amplifier
LP Filter
MIC_A_N
SPKR_A_N
MIC_B_P
SPKR_B_P
MIC_B_N
SPKR_B_N
-ADCΣΔ
- DACΣΔ
- DACΣΔ
-ADCΣΔ
Figure 10.2: Stereo CODEC Audio Input and Output Stages
The Stereo audio CODEC uses a fully differential architecture in the analogue signal path, which results in low noise
sensitivity and good power supply rejection while effectively doubling the signal amplitude. It operates from a single
power-supply of 1.5V and uses a minimum of external components.
10.2.2 Stereo CODEC Set-up
The configuration and control of the ADC is through VM functions described in appropriate BlueLab Multimedia
documentation. This section is an overview of the parameters that can be set up using the VM functions.
The Kalimba DSP can communicate its CODEC requirements to the MCU, and therefore also to the VM, by exchange
of messages. The messages used between the Kalimba DSP and the embedded MCU are based on interrupts:
1 interrupt between the MCU and Kalimba DSP
1 interrupt between the Kalimba DSP and the MCU
Message content is transmitted using shared memory. There are VM and DSP library functions to send and receive
messages; refer to BlueLab Multimedia documentation for further details.
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10.2.3 ADC
The ADC consists of:
Two second-order Sigma Delta converters allowing two separate channels that are identical in functionality,
as shown in Figure 10.2.
Two gain stages for each channel, one of which is an analogue gain stage and the other is a digital gain
stage.
10.2.4 ADC Sample Rate Selection
Each ADC supports the following sample rates:
8kHz
11.025kHz
16kHz
22.05kHz
24kHz
32kHz
44.1kHz
10.2.5 ADC Digital Gain
The digital gain stage has a programmable selection value in the range of 0 to 15 with the associated ADC gain
settings summarised in Table 10.2. There is also a high resolution digital gain mode that allows the gain to be
changed in 1/32dB steps. Contact CSR for more information.
Gain Selection Value ADC Digital Gain Setting (dB)
0 0
13.5
2 6
39.5
412
515.5
618
721.5
8-24
9-20.5
10 -18
11 -14.5
12 -12
13 -8.5
14 -6
15 -2.5
Table 10.2: ADC Digital Gain Rate Selection
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10.2.6 ADC Analogue Gain
Figure 10.3 shows the equivalent block diagram for the ADC analogue amplifier. It is a two-stage amplifier:
The first stage amplifier has a selectable gain of either bypass for line input mode or gain of 24dB gain for
the microphone mode.
The second stage has a programmable gain with seven individual 3dB steps. By combining the 24dB gain
selection of the microphone input with the seven individual 3dB gain steps, the overall range of the analogue
amplifier is approximately -3dB to 42dB in 3dB steps. All gain control of the ADC is controlled by a a VM
function.
Bypass or 24dB gain -3dB to 18dB gain
Gain 0:7
Line Mode / Mic Mode
P
N
P
N
Switches shown for Line Mod
e
Microphone Mode input impedance = 6k Ω
Line mode input impedance = 6k to 30kΩΩ
Figure 10.3: ADC Analogue Amplifier Block Diagram
10.2.7 DAC
The DAC consists of:
Two second-order Sigma Delta converters allowing two separate channels that are identical in functionality,
as shown in Figure 10.2.
Two gain stages for each channel, one of which is an analogue gain stage and the other is a digital gain
stage.
10.2.8 DAC Sample Rate Selection
Each DAC supports the following samples rates:
8kHz
11.025kHz
12kHz
16kHz
22.050kHz
24kHz
32kHz
44.1kHz
48kHz
10.2.9 DAC Digital Gain
The digital gain stage has a programmable selection value in the range of 0 to 15 with associated DAC gain settings,
summarised in Table 10.3. There is also a high resolution digital gain mode that allows the gain to be changed in
1/32dB steps. Contact CSR for more information.
The overall gain control of the DAC is controlled by a VM function. Its setting is a combined function of the digital
and analogue amplifier settings.
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Digital Gain Selection Value DAC Digital Gain Setting (dB)
0 0
13.5
2 6
39.5
412
515.5
618
721.5
8-24
9 -20.5
10 -18
11 -14.5
12 -12
13 -8.5
14 -6
15 -2.5
Table 10.3: DAC Digital Gain Rate Selection
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10.2.10 DAC Analogue Gain
The DAC analogue gain stage consists of eight gain selection values that represent seven 3dB steps, as shown in
Table 10.4.
The overall gain control of the DAC is controlled by a VM function. Its setting is a combined function of the digital
and analogue amplifier settings.
Analogue Gain Selection Value DAC Analogue Gain Setting (dB)
7 3
6 0
5-3
4-6
3-9
2-12
1-15
0-18
Table 10.4: DAC Analogue Gain Rate Selection
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10.2.11 Microphone Input
The microphone for each channel should be biased as shown in Figure 10.4. The microphone bias, MIC_BIAS,
derives its power from the BAT_P and requires a 1µF capacitor on its output.
R2
C2
R1
C1
Microphone Bias
C3
C4
MIC_A_P
MIC_A_N
MIC1
+
Input
Amplifier
Figure 10.4: Microphone Biasing (Single Channel Shown)
The MIC_BIAS is like any voltage regulator and requires a minimum load to maintain regulation. The MIC_BIAS
maintains regulation within the limits 0.200 - 1.230mA. If the microphone sits below these limits, then the microphone
output must be pre-loaded with a large value resistor to ground.
The audio input is intended for use in the range from 1μA@94dB SPL to about 10μA@94dB SPL. With biasing
resistors R1 and R2 equal to 1kΩ, this requires microphones with sensitivity between about –40dBV and –60dBV.
The input impedance at MIC_A_N, MIC_A_P, MIC_B_N and MIC_B_P is typically 6.0kΩ.
C1 and C2 should be 150nF if bass roll-off is required to limit wind noise on the microphone.
R1 sets the microphone load impedance and is normally in a range of 1 - 2kΩ.
R2, C3 and C4 improve the supply rejection by decoupling supply noise from the microphone. Values should be
selected as required. R2 may be connected to a convenient supply, in which case the bias network is permanently
enabled, or to the MIC_BIAS output (which is ground referenced and provides good rejection of the supply), which
may be configured to provide bias only when the microphone is required.
The microphone bias provides a 4-bit programmable output voltage, shown in Table 10.5, with a 4-bit programmable
output current, shown in Table 10.6.
The characteristics of the microphone bias include:
Power supply:
BlueCore5‑Multimedia Flash microphone supply is BAT_P
Minimum input voltage = Output voltage + drop-out voltage
Maximum input voltage is 4.4V
Typically the microphone bias is at the same level as VDD_AUDIO (1.5V)
Drop-out voltage:
300mV minimum
Guaranteed for configuration of voltage or current output shown in Table 10.5 and Table 10.6
Output voltage:
4-bit programmable between 1.7 - 3.6V
Tolerance 90 - 110%
Output current:
4-bit programmable between 200uA – 1.230mA
Maximum current guaranteed to be >1mA
Load capacitance:
Unconditionally stable for 1uF ±20% and 2.2uF ±20% pure C
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Output Step VOL_SET[3:0] Min Typ Max Units
0
0000
-1.71 - V
1
0001
-1.76 - V
2
0010
-1.82 - V
3
0011
-1.87 - V
4
0100
-1.95 - V
5
0101
-2.02 - V
6
0110
-2.10 - V
7
0111
-2.18 - V
8
1000
-2.32 - V
9
1001
-2.43 - V
10
1010
-2.56 - V
11
1011
-2.69 - V
12
1100
-2.90 - V
13
1101
-3.08 - V
14
1110
-3.33 - V
15
1111
-3.57 - V
Table 10.5: Voltage Output Steps
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Output Step CUR_SET[3:0] Typ Units
0
0000
0.200 mA
1
0001
0.280 mA
2
0010
0.340 mA
3
0011
0.420 mA
4
0100
0.480 mA
5
0101
0.530 mA
6
0110
0.610 mA
7
0111
0.670 mA
8
1000
0.750 mA
9
1001
0.810 mA
10
1010
0.860 mA
11
1011
0.950 mA
12
1100
1.000 mA
13
1101
1.090 mA
14
1110
1.140 mA
15
1111
1.230 mA
Table 10.6: Current Output Steps
Note:
For BAT_P, the PSRR @ 100Hz - 22kHz, with >300mV supply headroom, decoupling capacitor of 1.1μF, is
typically 58.9dB and worst case 53.4dB.
For VDD_AUDIO, the PSRR @ 100Hz - 22kHz, decoupling capacitor of 1.1μF, is typically 88dB and worst case
60dB.
10.2.12 Line Input
If the input analogue gain is set to less than 24dB, BlueCore5‑Multimedia Flash automatically selects line input mode.
In line input mode the first stage of the amplifier is automatically disabled, providing additional power saving. In line
input mode the input impedance varies from 6kΩ - 30kΩ, depending on the volume setting. Figure 10.5 and Figure
10.6 show two circuits for line input operation and show connections for either differential or single-ended inputs.
C1
C2
MIC_A_P
MIC_A_N
Figure 10.5: Differential Input (Single Channel Shown)
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C1
C2
MIC_A_P
MIC_A_N
Figure 10.6: Single-Ended Input (Single Channel Shown)
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10.2.13 Output Stage
The output stage digital circuitry converts the signal from 16-bit per sample, linear PCM of variable sampling
frequency to bit stream, which is fed into the analogue output circuitry.
The output stage circuit comprises a DAC with gain setting and class AB output stage amplifier. The output is
available as a differential signal between SPKR_A_N and SPKR_A_P for the left channel, as shown in Figure
10.7, and between SPKR_B_N and SPKR_B_P for the right channel.
The output stage is capable of driving a speaker directly when its impedance is at least and an external regulator
is used, but this will be at a reduced output swing.
SPKR_A_P
SPKR_A_N
Figure 10.7: Speaker Output (Single Channel Shown)
The analogue gain of the output stage is controlled by a 3-bit programmable resistive divider, which sets the gain in
steps of approximately 3dB.
10.2.14 Mono Operation
Mono operation is a single-channel operation of the stereo CODEC. The left channel represents the single mono
channel for audio in and audio out. In mono operation the right channel is auxilliary mono channel that may be used
in dual mono channel operation.
With single mono, the power consumption can be reduced by disabling the other channel.
Important Note:
For mono operation this data sheet uses the left channel for standard mono operation for audio input and output
and with respect to software and any registers, channel 0 or channel A represents the standard mono channel
for audio input and output. In mono operation the second channel which is the right channel, channel 1 or channel
B could be used as a second mono channel if required and this channel is referred to as the auxilliary mono
channel for audio input and output.
10.2.15 Side Tone
In some applications it is necessary to implement side tone. This involves feeding an attenuated version of the
microphone signal to the earpiece. The BlueCore5‑Multimedia Flash CODEC contains side tone circuitry to do this.
The side tone hardware is configured through the the following PS Keys:
SIDE_TONE_ENABLE
SIDE_TONE_GAIN
SIDE_TONE_AFTER_ADC
SIDE_TONE_AFTER_DAC
10.2.16 Integrated Digital Filter
BlueCore5‑Multimedia Flash has a programmable digital filter integrated into the ADC channel of the CODEC. The
filter is a two stage, second order
infinite impulse response
(IIR) and can be used for functions such as custom wind
noise rejection. The filter also has optional DC blocking.
The filter has 10 configuration words used as follows:
1 for gain value
8 for coefficient values
1 for enabling and disabling the DC blocking
The gain and coefficients are all 12-bit 2's complement signed integer with the format
XX.XXXXXXXXXX
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Note:
The position of the binary point is between bit 10 and bit 9, where bit 11 is the most significant bit.
For example:
01.1111111111
=most positive number, close to
+2
01.0000000000
=
1
00.0000000000
=
0
11.0000000000
=
-1
10.0000000000
=
-2
, most negative number
The equation for the IIR filter is shown in Equation 10.1. When the DC blocking is enabled the equation is shown in
Equation 10.2.
The filter can be configured, enabled and disabled from the VM via the
CodecSetIIRFilterA
and
CodecSetIIRFilterB
traps
1
. The configuration function takes 10 variables in the order shown below:
0
:Gain
1
:b
01
2
:b
02
3
:a
01
4
:a
02
5
:b
11
6
:b
12
7
:a
11
8
:a
12
9
: DC Block (1 = enable, 0 = disable)
Filter, H(z) = Gain ×
(1+b
01 z−1 +b
02 z−2 )
(1+a
01 z−1 +a
02 z−2 )
×
(1+b
11 z−1 +b
12 z−2 )
(1+a
11 z−1 +a
12 z−2 )
Equation 10.1: IIR Filter Transfer Function, H(z)
Filter with DC Blocking, H
DC
(z) = H(z) × (1−z
−1
)
Equation 10.2: IIR Filter plus DC Blocking Transfer Function, H
DC
(z)
10.3 PCM Interface
The audio
pulse code modulation
(PCM) interface supports continuous transmission and reception of PCM encoded
audio data over Bluetooth.
1
Requires firmware support
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PCM is a standard method used to digitise audio (particularly voice) for transmission over digital communication
channels. Through its PCM interface, BlueCore5‑Multimedia Flash has hardware support for continual transmission
and reception of PCM data, so reducing processor overhead for wireless headset applications.
BlueCore5‑Multimedia Flash offers a bi-directional digital audio interface that routes directly into the baseband layer
of the on-chip firmware. It does not pass through the HCI protocol layer.
Hardware on BlueCore5‑Multimedia Flash allows the data to be sent to and received from a SCO connection.
Up to three SCO connections can be supported by the PCM interface at any one time.
BlueCore5‑Multimedia Flash can operate as the PCM interface master generating PCM_SYNC and PCM_CLK or
as a PCM interface slave accepting externally generated PCM_SYNC and PCM_CLK. BlueCore5‑Multimedia Flash
is compatible with various clock formats, including Long Frame Sync, Short Frame Sync and GCI timing
environments.
It supports 13-bit or 16-bit linear, 8-bit µ-law or A-law companded sample formats, and can receive and transmit on
any selection of three of the first four slots following PCM_SYNC. The PCM configuration options are enabled by
setting the PS Key PS KEY_PCM_CONFIG32 (0x1b3).
10.3.1 PCM Interface Master/Slave
When configured as the master of the PCM interface, BlueCore5‑Multimedia Flash generates PCM_CLK and
PCM_SYNC.
PCM_SYNC
PCM_OUT
PCM_IN
PCM_CLK 128/256/512/1536/2400kHz
8/48kHz
Figure 10.8: PCM Interface Master
Upto 2400kHz
8/48kHz
PCM_OUT
PCM_IN
PCM_CLK
PCM_SYNC
Figure 10.9: PCM Interface Slave
10.3.2 Long Frame Sync
Long Frame Sync is the name given to a clocking format that controls the transfer of PCM data words or samples.
In Long Frame Sync, the rising edge of PCM_SYNC indicates the start of the PCM word. When
BlueCore5‑Multimedia Flash is configured as PCM master, generating PCM_SYNC and PCM_CLK, then
PCM_SYNC is 8-bits long. When BlueCore5‑Multimedia Flash is configured as PCM Slave, PCM_SYNC may be
from one cycle PCM_CLK to half the PCM_SYNC rate.
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PCM_SYNC
PCM_CLK
PCM_OUT
PCM_IN
1 2 3 4 5 6 7 8
1 2 3 4 5 6 7 8
Undefined Undefined
Figure 10.10: Long Frame Sync (Shown with 8-bit Companded Sample)
BlueCore5‑Multimedia Flash samples PCM_IN on the falling edge of PCM_CLK and transmits PCM_OUT on the
rising edge. PCM_OUT may be configured to be high impedance on the falling edge of PCM_CLK in the LSB position
or on the rising edge.
10.3.3 Short Frame Sync
In Short Frame Sync, the falling edge of PCM_SYNC indicates the start of the PCM word. PCM_SYNC is always
one clock cycle long.
PCM_SYNC
PCM_CLK
PCM_OUT
PCM_IN
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 UndefinedUndefined
Figure 10.11: Short Frame Sync (Shown with 16-bit Sample)
As with Long Frame Sync, BlueCore5‑Multimedia Flash samples PCM_IN on the falling edge of PCM_CLK and
transmits PCM_OUT on the rising edge. PCM_OUT may be configured to be high impedance on the falling edge of
PCM_CLK in the LSB position or on the rising edge.
10.3.4 Multi-slot Operation
More than one SCO connection over the PCM interface is supported using multiple slots. Up to three SCO
connections can be carried over any of the first four slots.
LONG_PCM_SYNC
Or
SHORT_PCM_SYNC
PCM_CLK
PCM_OUT
PCM_IN
1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8
1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 Do Not CareDo Not Care
Figure 10.12: Multi-slot Operation with Two Slots and 8-bit Companded Samples
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10.3.5 GCI Interface
BlueCore5‑Multimedia Flash is compatible with the
General Circuit Interface
(GCI), a standard synchronous 2B+D
ISDN timing interface. The two 64kbps B channels can be accessed when this mode is configured.
PCM_SYNC
PCM_CLK
PCM_OUT
PCM_IN
1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8
1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8
Do Not
Care
Do Not
Care
B1 Channel B2 Channel
Figure 10.13: GCI Interface
The start of frame is indicated by the rising edge of PCM_SYNC and runs at 8kHz.
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10.3.6 Slots and Sample Formats
BlueCore5‑Multimedia Flash can receive and transmit on any selection of the first four slots following each sync
pulse. Slot durations can be either 8 or 16 clock cycles. Durations of 8 clock cycles may only be used with 8-bit
sample formats. Durations of 16 clocks may be used with 8-bit, 13-bit or 16-bit sample formats.
BlueCore5‑Multimedia Flash supports 13-bit linear, 16-bit linear and 8-bit µ-law or A-law sample formats. The sample
rate is 8ksamples/s. The bit order may be little or big endian. When 16-bit slots are used, the 3 or 8 unused bits in
each slot may be filled with sign extension, padded with zeros or a programmable 3-bit audio attenuation compatible
with some Motorola CODECs.
PCM_OUT
PCM_OUT
PCM_OUT
PCM_OUT
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
Sign
Extension
8-Bit
Sample
8-Bit
Sample
Zeros
Padding
Sign
Extension
13-Bit
Sample
13-Bit
Sample
Audio
Gain
A 16-bit slot with 8-bit companded sample and sign extension selected.
A 16-bit slot with 8-bit companded sample and zeros padding selected.
A 16-bit slot with 13-bit linear sample and sign extension selected.
A 16-bit slot with 13-bit linear sample and audio gain selected.
Figure 10.14: 16-Bit Slot Length and Sample Formats
10.3.7 Additional Features
BlueCore5‑Multimedia Flash has a mute facility that forces PCM_OUT to be 0. In master mode, PCM_SYNC may
also be forced to 0 while keeping PCM_CLK running which some CODECs use to control power down.
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10.3.8 PCM Timing Information
Symbol Parameter Min Typ Max Unit
f
mclk
PCM_CLK frequency
4MHz DDS generation.
Selection of frequency
is programmable. See
Table 10.10.
-
128
-kHz
256
512
48MHz DDS
generation. Selection
of frequency is
programmable. See
Table 10.9 and Section
10.3.9.
2.9 - - kHz
-PCM_SYNC frequency for SCO connection - 8 - kHz
t
mclkh
(a)
PCM_CLK high 4MHz DDS generation 980 - - ns
t
mclkl
(a)
PCM_CLK low 4MHz DDS generation 730 - - ns
-PCM_CLK jitter 48MHz DDS
generation - - 21 ns pk-pk
t
dmclksynch
Delay time from PCM_CLK high to PCM_SYNC
high - - 20 ns
t
dmclkpout
Delay time from PCM_CLK high to valid
PCM_OUT - - 20 ns
t
dmclklsyncl
Delay time from PCM_CLK low to PCM_SYNC
low (Long Frame Sync only) - - 20 ns
t
dmclkhsyncl
Delay time from PCM_CLK high to PCM_SYNC
low - - 20 ns
t
dmclklpoutz
Delay time from PCM_CLK low to PCM_OUT
high impedance - - 20 ns
t
dmclkhpoutz
Delay time from PCM_CLK high to PCM_OUT
high impedance - - 20 ns
t
supinclkl
Set-up time for PCM_IN valid to PCM_CLK low 30 - - ns
t
hpinclkl
Hold time for PCM_CLK low to PCM_IN invalid 10 - - ns
Table 10.7: PCM Master Timing
(a)
Assumes normal system clock operation. Figures will vary during low power modes, when system clock speeds are reduced.
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PCM_SYNC
PCM_CLK
PCM_OUT
PCM_IN
MSB (LSB) LSB (MSB)
MSB (LSB) LSB (MSB)
f
mlk
t
mclkh
t
mclkl
t
supinclkl
t
dmclksynch
t
dmclkpout
t
hpinclkl
t
dmclklsyncl
t
dmclkhsyncl
t
dmclklpoutz
t
dmclkhpoutz
t
r
,t
f
Figure 10.15: PCM Master Timing Long Frame Sync
PCM_SYNC
PCM_CLK
PCM_OUT
PCM_IN
MSB (LSB) LSB (MSB)
MSB (LSB) LSB (MSB)
f
mlk
t
mclkh
t
mclkl
t
supinclkl
t
t
dmclkpout
t
hpinclkl
dmclkhsyncl
t
dmclklpoutz
t
dmclkhpoutz
t
r
,t
f
t
dmclksynch
Figure 10.16: PCM Master Timing Short Frame Sync
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Symbol Parameter Min Typ Max Unit
f
sclk
PCM clock frequency (Slave mode: input) 64 -
(a)
kHz
f
sclk
PCM clock frequency (GCI mode) 128 -
(b)
kHz
t
sclkl
PCM_CLK low time 80 - - ns
t
sclkh
PCM_CLK high time 80 - - ns
t
hsclksynch
Hold time from PCM_CLK low to PCM_SYNC high 20 - - ns
t
susclksynch
Set-up time for PCM_SYNC high to PCM_CLK low 20 - - ns
t
dpout
Delay time from PCM_SYNC or PCM_CLK
whichever is later, to valid PCM_OUT data (Long
Frame Sync only)
- - 20 ns
t
dsclkhpout
Delay time from CLK high to PCM_OUT valid data - - 20 ns
t
dpoutz
Delay time from PCM_SYNC or PCM_CLK low,
whichever is later, to PCM_OUT data line high
impedance
- - 20 ns
t
supinsclkl
Set-up time for PCM_IN valid to CLK low 20 - - ns
t
hpinsclkl
Hold time for PCM_CLK low to PCM_IN invalid 20 - - ns
Table 10.8: PCM Slave Timing
(a)
Max frequency is the frequency defined by PSKEY_PCM_MIN_CPU_CLOCK
(b)
Max frequency is twice the frequency defined by PSKEY_PCM_MIN_CPU_CLOCK
PCM_CLK
PCM_SYNC
PCM_OUT
PCM_IN MSB (LSB) LSB (MSB)
f
sclk
t
sclkh
t
tsclkl
t
hsclksynch
t
susclksynch
t
dpout
t
dsclkhpout
t
dpoutz
t
dpoutz
t
supinsclkl
t
hpinsclkl
t
r
,t
f
LSB (MSB)
MSB (LSB)
Figure 10.17: PCM Slave Timing Long Frame Sync
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PCM_CLK
PCM_SYNC
PCM_OUT
PCM_IN MSB (LSB) LSB (MSB)
f
sclk
t
sclkh
t
tsclkl
t
hsclksynch
t
susclksynch
t
dpoutz
t
dpoutz
t
supinsclkl
t
hpinsclkl
t
r
,t
f
LSB (MSB)
MSB (LSB)
t
dsclkhpout
Figure 10.18: PCM Slave Timing Short Frame Sync
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10.3.9 PCM_CLK and PCM_SYNC Generation
BlueCore5‑Multimedia Flash has two methods of generating PCM_CLK and PCM_SYNC in master mode:
Generating these signals by
Direct Digital Synthesis
(DDS) from BlueCore5‑Multimedia Flash internal
4MHz clock. Using this mode limits PCM_CLK to 128, 256 or 512kHz and PCM_SYNC to 8kHz.
Generating these signals by DDS from an internal 48MHz clock (which allows a greater range of frequencies
to be generated with low jitter but consumes more power). This second method is selected by setting bit
48M_PCM_CLK_GEN_EN in PSKEY_PCM_CONFIG32. When in this mode and with long frame sync, the
length of PCM_SYNC can be either 8 or 16 cycles of PCM_CLK, determined by
LONG_LENGTH_SYNC_EN in PSKEY_PCM_CONFIG32.
Equation 10.3 describes PCM_CLK frequency when being generated using the internal 48MHz clock:
MHz24
LIMIT_CNT
RATE_CNT
f×=
Equation 10.3: PCM_CLK Frequency When Being Generated Using the Internal 48MHz Clock
Set the frequency of PCM_SYNC relative to PCM_CLK using Equation 10.4:
LIMIT x
8
_
SYN
CLK
_
PC
M
f
=
Equation 10.4: PCM_SYNC Frequency Relative to PCM_CLK
CNT_RATE, CNT_LIMIT and SYNC_LIMIT are set using PSKEY_PCM_LOW_JITTER_CONFIG. As an example, to
generate PCM_CLK at 512kHz with PCM_SYNC at 8kHz, set PSKEY_PCM_LOW_JITTER_CONFIG to
0x08080177.
10.3.10 PCM Configuration
The PCM configuration is set using the PS Keys, PSKEY_PCM_CONFIG32 described in Table 10.10 and
PSKEY_PCM_LOW_JITTER_CONFIG in Table 10.9. The default for PSKEY_PCM_CONFIG32 is 0x00800000, i.e.,
first slot following sync is active, 13-bit linear voice format, long frame sync and interface master generating 256kHz
PCM_CLK from 4MHz internal clock with no tri-state of PCM_OUT.
Name Bit Position Description
CNT_LIMIT [12:0] Sets PCM_CLK counter limit
CNT_RATE [23:16] Sets PCM_CLK count rate
SYNC_LIMIT [31:24] Sets PCM_SYNC division relative to PCM_CLK
Table 10.9: PSKEY_PCM_LOW_JITTER_CONFIG Description
Name Bit Position Description
- 0 Set to 0.
SLAVE_MODE_EN 1
0 = master mode with internal generation of PCM_CLK and
PCM_SYNC.
1 = slave mode requiring externally generated PCM_CLK
and PCM_SYNC.
SHORT_SYNC_EN 20 = long frame sync (rising edge indicates start of frame).
1 = short frame sync (falling edge indicates start of frame).
- 3 Set to 0.
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Name Bit Position Description
SIGN_EXTEND_EN 4
0 = padding of 8 or 13-bit voice sample into a 16-bit slot by
inserting extra LSBs. When padding is selected with 13-bit
voice sample, the 3 padding bits are the audio gain setting;
with 8-bit sample the 8 padding bits are zeroes.
1 = sign-extension.
LSB_FIRST_EN 50 = MSB first of transmit and receive voice samples.
1 = LSB first of transmit and receive voice samples.
TX_TRISTATE_EN 6
0 = drive PCM_OUT continuously.
1 = tri-state PCM_OUT immediately after falling edge of
PCM_CLK in the last bit of an active slot, assuming the
next slot is not active.
TX_TRISTATE_RISING_EDGE_EN 7
0 = tri-state PCM_OUT immediately after falling edge of
PCM_CLK in last bit of an active slot, assuming the next
slot is also not active.
1 = tri-state PCM_OUT after rising edge of PCM_CLK.
SYNC_SUPPRESS_EN 8
0 = enable PCM_SYNC output when master.
1 = suppress PCM_SYNC while keeping PCM_CLK
running. Some CODECs use this to enter a low power
state.
GCI_MODE_EN 91 = enable GCI mode.
MUTE_EN 10 1 = force PCM_OUT to 0.
48M_PCM_CLK_GEN_EN 11
0 = set PCM_CLK and PCM_SYNC generation via DDS
from internal 4MHz clock.
1 = set PCM_CLK and PCM_SYNC generation via DDS
from internal 48MHz clock.
LONG_LENGTH_SYNC_EN 12
0 = set PCM_SYNC length to 8 PCM_CLK cycles.
1 = set length to 16 PCM_CLK cycles.
Only applies for long frame sync and with
48M_PCM_CLK_GEN_EN set to 1.
-[20:16] Set to
0b00000
.
MASTER_CLK_RATE [22:21]
Selects 128 (
0b01
), 256 (
0b00
), 512 (
0b10
) kHz
PCM_CLK frequency when master and
48M_PCM_CLK_GEN_EN (bit 11) is low.
ACTIVE_SLOT [26:23] Default is 0001. Ignored by firmware.
SAMPLE_FORMAT [28:27]
Selects between 13 (
0b00
), 16 (
0b01
), 8 (
0b10
) bit
sample with 16-cycle slot duration or 8 (
0b11
) bit sample
with 8-cycle slot duration.
Table 10.10: PSKEY_PCM_CONFIG32 Description
10.4 Digital Audio Interface (I²S)
The digital audio interface supports the industry standard formats for I
2
S,
left-justified
(LJ) or
right-justified
(RJ). The
interface shares the same pins as the PCM interface, which means each audio bus is mutually exclusive in its usage.
Table 10.11 lists these alternative functions. Figure 10.19 shows the timing diagram.
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PCM Interface I
2
S Interface
PCM_OUT SD_OUT
PCM_IN SD_IN
PCM_SYNC WS
PCM_CLK SCK
Table 10.11: Alternative Functions of the Digital Audio Bus Interface on the PCM Interface
Table 10.12 describes the values for the PS Key (PSKEY_DIGITAL_AUDIO_CONFIG) that is used to set-up the
digital audio interface. For example, to configure an I
2
S interface with 16-bit SD data set PSKEY_DIGITAL_CONFIG
to 0x0406.
Bit Mask Name Description
D[0] 0x0001 CONFIG_JUSTIFY_FORMAT 0 for left justified, 1 for right justified.
D[1] 0x0002 CONFIG_LEFT_JUSTIFY_DELAY
For left justified formats: 0 is MSB of SD data
occurs in the first SCLK period following WS
transition. 1 is MSB of SD data occurs in the
second SCLK period.
D[2] 0x0004 CONFIG_CHANNEL_POLARITY For 0, SD data is left channel when WS is
high. For 1 SD data is right channel.
D[3] 0x0008 CONFIG_AUDIO_ATTEN_EN
For 0, 17 bit SD data is rounded down to 16
bits. For 1, the audio attenuation defined in
CONFIG_AUDIO_ATTEN is applied over 24
bits with saturated rounding. Requires
CONFIG_16_BIT_CROP_EN to be 0.
D[7:4] 0x00F0 CONFIG_AUDIO_ATTEN Attenuation in 6 dB steps.
D[9:8] 0x0300 CONFIG_JUSTIFY_RESOLUTION
Resolution of data on SD_IN, 00=16 bit,
01=20 bit, 10=24 bit, 11=Reserved. This is
required for right justified format and with left
justified LSB first.
D[10] 0x0400 CONFIG_16_BIT_CROP_EN
For 0, 17 bit SD_IN data is rounded down to
16 bits. For 1 only the most significant 16 bits
of data are received.
Table 10.12: PSKEY_DIGITAL_AUDIO_CONFIG
Audio Interface
CS-113071-DSP2
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WS
SCK
SD_IN/OUT
WS
SCK
SD_IN/OUT
WS
SCK
SD_IN/OUT
LSB
MSB LSB MSB LSB
MSB LSB MSB LSB
Left-Justified Mode
Right-Justified Mode
Left Channel Right Channel
Right ChannelLeft Channel
Left Channel Right Channel
MSB LSB MSB
I
2
S Mode
Figure 10.19: Digital Audio Interface Modes
The internal representation of audio samples within BlueCore5‑Multimedia Flash is 16-bit and data on SD_OUT is
limited to 16-bit per channel.
Audio Interface
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Symbol Parameter Min Typ Max Unit
-SCK Frequency - - 6.2 MHz
-WS Frequency - - 96 kHz
t
ch
SCK high time 80 - - ns
t
cl
SCK low time 80 - - ns
t
opd
SCK to SD_OUT delay - - 20 ns
t
ssu
WS to SCK set-up time 20 - - ns
t
sh
WS to SCK hold time 20 - - ns
t
isu
SD_IN to SCK set-up time 20 - - ns
t
ih
SD_IN to SCK hold time 20 - - ns
Table 10.13: Digital Audio Interface Slave Timing
SD_OUT
SD_IN
t
t
t
t
t
t
WS(Input)
SCK(Input)
ch
opd
ih
shssu
cl
isu
t
Figure 10.20: Digital Audio Interface Slave Timing
Audio Interface
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Symbol Parameter Min Typ Max Unit
-SCK Frequency - - 6.2 MHz
-WS Frequency - - 96 kHz
t
opd
SCK to SD_OUT delay - - 20 ns
t
spd
SCK to WS delay - - 20 ns
t
isu
SD_IN to SCK set-up time 20 - - ns
t
ih
SD_IN to SCK hold time 10 - - ns
Table 10.14: Digital Audio Interface Master Timing
WS(Output)
SCK(Output)
SD_OUT
SD_IN
t
isu
t
ih
t
opd
t
spd
Figure 10.21: Digital Audio Interface Master Timing
Audio Interface
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11 Power Control and Regulation
BlueCore5‑Multimedia Flash contains four regulators:
Two high-voltage regulators, either of which can generate a 1.8V supply rail.
Two low-voltage regulators, running in parallel to supply the 1.5V core supplies from a 1.8V supply rail.
Various configurations for power control and regulation with the BlueCore5‑Multimedia Flash are available:
A high-voltage rail running a high-voltage regulator and the low-voltage regulators in series, as shown in
Figure 11.1.
BlueCore5‑Multimedia Flash powered directly from an external 1.8V supply rail, by-passing the high-voltage
regulator
An external 1.5V rail omitting all regulators
VDD_SMP_CORE
LX
Switch Mode
Regulator
SENSEEN
LX
Battery Charger
OUT
IN
L1
C1
Audio Low
Voltage Regulator
OUT
IN
EN
VREGIN_AUDIO
VDD_AUDIO
VREGENABLE_L
VREGIN_L
VREGIN_H
VREGOUT_H
VREGENABLE_H
VDD_RADIO
Low Voltage
Linear Regulator
OUT
SENSE
SENSE
IN
EN
VDD_ANA
High Voltage
Linear Regulator
OUT
IN
EN
SENSE
1.8V Supply Rail
BAT_P
BAT_N
VDD_CHG
1.8V Supply Rail
Figure 11.1: Voltage Regulator Configuration
11.1 Power Sequencing
The 1.50V supply rails are VDD_ANA, VDD_AUDIO, VDD_CORE, VDD_LO and VDD_RADIO. CSR recommends
that these supply rails are all powered at the same time.
The digital I/O supply rails are VDD_PADS, VDD_PIO and VDD_USB.
The sequence of powering the 1.50V supply rails relative to the digital I/O supply rails is not important. If the digital
I/O supply rails are powered before the 1.50V supply rails, all digital I/Os will have a weak pull-down irrespective of
the reset state.
VDD_ANA, VDD_AUDIO, VDD_LO and VDD_RADIO can connect directly to a 1.50V supply.
Power Control and Regulation
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A simple RC filter is recommended for VDD_CORE to reduce transients fed back onto the power supply rails.
The digital I/O supply rails are connected together or independently to an appropriate voltage rail. Decoupling of the
digital I/O supply rails is recommended.
11.2 External Voltage Source
If any of the supply rails for BlueCore5‑Multimedia Flash are supplied from an external voltage source, rather than
one of the internal voltage regulators, then it is recommended that VDD_AUDIO, VDD_LO and VDD_RADIO should
have less than 10mV rms noise levels between 0 to 10MHz. Also avoid single tone frequencies.
The transient response of any external regulator used should match or be better than the internal regulator available
on BlueCore5‑Multimedia Flash. (Refer to regulator characteristics in Section 13.) It is essential that the power rail
recovers quickly at the start of a packet, where the power consumption jumps to high levels.
11.3 Switch-mode Regulator
The on-chip switch-mode regulator is available to power a 1.8V supply rail.
An external
inductor-capacitor
(LC) filter circuit of a low-resistance series inductor, L1 (22µH), followed by a low ESR
shunt capacitor, C1 (4.7µF), is required between the LX terminal and the 1.8V supply rail. A connection between the
1.8V supply rail and the VDD_SMP_CORE pin is required.
A decoupling capacitor (2.2µF) is required between BAT_P and BAT_N.
To maintain high-efficiency power conversion and low supply ripple, it is essential that the series resistance of tracks
between the BAT_P and BAT_N terminals, the filter and decoupling components, and the external voltage source
are minimised.
The switch-mode regulator is enabled by either:
VREGENABLE_H pin
BlueCore5‑Multimedia Flash device firmware
BlueCore5‑Multimedia Flash battery charger
The switch-mode regulator is switched into a low-power pulse skipping mode when the device is sent into deep-
sleep mode, or in reset.
When the switch-mode regulator is not required the terminals BAT_P and LX must be grounded or left unconnected.
11.4 High-voltage Linear Regulator
The high-voltage linear regulator is available to power a 1.8V supply rail.
A smoothing circuit using a low ESR 2.2µF capacitor and a 2.2Ω resistor to ground, should be connected to the
output of the high-voltage linear regulator, VREGOUT_H. Alternatively use a 2.2µF capacitor with an ESR of at least
2Ω.
The high-voltage linear regulator is enabled by either:
VREGENABLE_H pin
BlueCore5‑Multimedia Flash device firmware
BlueCore5‑Multimedia Flash battery charger
The regulator is switched into a low-power mode when the device is in deep-sleep mode, or in reset.
When the high-voltage linear regulator is not used the terminals VREGIN_H and VREGOUT_H must be left
unconnected, or tied to ground.
11.5 Low-voltage Linear Regulator
The low-voltage linear regulator is available to power a 1.5V supply rail. Its output is connected internally to
VDD_ANA, and can be connected externally to the other 1.5V power inputs.
If the low-voltage linear regulator is used a smoothing circuit using a low ESR 2.2µF capacitor and a 2.2Ω resistor
to ground, should be connected to the output of the low-voltage linear regulator, VDD_ANA. Alternatively use a 2.2µF
capacitor with an ESR of at least 2Ω.
The low-voltage linear regulator is enabled by either:
VREGENABLE_L pin
BlueCore5‑Multimedia Flash device firmware
BlueCore5‑Multimedia Flash battery charger
Power Control and Regulation
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The low-voltage linear regulator is switched into a low power mode when the device is in deep-sleep mode, or in
reset.
When the low-voltage linear regulator is not used the terminal VREGIN_L must be left unconnected, or tied to
VDD_ANA.
11.6 Low-voltage Audio Linear Regulator
The low-voltage audio linear regulator is available to power a 1.5V audio supply rail. Its output is connected internally
to VDD_AUDIO, and can be connected externally to the other 1.5V audio power inputs.
If the low-voltage audio linear regulator is used a smoothing circuit using a low ESR 2.2µF capacitor and a 2.2Ω
resistor to ground, should be connected to the output of the low-voltage linear regulator, VDD_AUDIO. Alternatively
use a 2.2µF capacitor with an ESR of at least 2Ω.
The low-voltage audio linear regulator is enabled by either:
VREGENABLE_L pin
BlueCore5‑Multimedia Flash device firmware
BlueCore5‑Multimedia Flash battery charger
The low-voltage audio linear regulator is switched into a low-power mode when no audio cells are enabled, or when
the chip is in reset.
When this regulator is not used the terminal VREGIN_AUDIO must be left unconnected or tied to VDD_AUDIO.
11.7 Voltage Regulator Enable Pins
The voltage regulator enable pins, VREGENABLE_H and VREGENABLE_L, are used to enable the
BlueCore5‑Multimedia Flash device if the on-chip regulators are being used. Table 11.1 shows the enable pin
responsible for each voltage regulator.
Enable Pin Regulator
VREGENABLE_H High-voltage Linear Regulator and Switch-mode Regulator
VREGENABLE_L Low-voltage Linear Regulator and Low-voltage Audio Linear Regulator
Table 11.1: BlueCore5‑Multimedia Flash Voltage Regulator Enable Pins
The voltage regulator enable pins are active high, with weak pull-downs.
BlueCore5‑Multimedia Flash boots-up when the voltage regulator enable pins are pulled high, enabling the
appropriate regulators. The firmware then latches the regulators on and the voltage regulator enable pins may then
be released.
The status of the VREGENABLE_H pin is available to firmware through an internal connection. VREGENABLE_H
also works as an input line.
11.8 Battery Charger
The battery charger is a constant current / constant voltage charger circuit, and is suitable for lithium ion/polymer
batteries only. It shares a connection to the battery terminal, BAT_P, with the switch-mode regulator. However it may
be used in conjunction with either of the high-voltage regulators on the device.
The constant current level can be varied to allow charging of different capacity batteries.
The charger enters various states of operation as it charges a battery, as listed below. A full operational description
is in
BlueCore5 Charger Description and Calibration Application Note
:
Power Control and Regulation
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Off : entered when charger disconnected.
Trickle charge: entered when battery is below 2.9V. The battery is charged at a nominal 4.5mA. This mode
is for the safe charge of deeply discharged cells.
Fast charge constant current: entered when battery is above 2.9V. The charger enters the main fast charge
mode. This mode charges the battery at the selected constant current, I
chgset
.
Fast charge constant voltage: entered when battery has reached a selected voltage, V
float
. The charger
switches mode to maintain the cell voltage at the V
float
voltage by adjusting the charge current.
Standby: this is the state when the battery is fully charged and no charging takes place. The battery voltage
is continuously monitored and if it drops by more than 150mV below the V
float
voltage the charger will re-
enter the fast charge constant current mode to keep the battery fully charged.
When a voltage is applied to the charger input terminal VDD_CHG, and the battery is not fully charged, the charger
operates and an LED connected to the terminal LED[0] illuminates. By default, until the firmware is running, the LED
pulses at a low-duty cycle to minimise current consumption.
The battery charger circuitry auto-detects the presence of a power source, allowing the firmware to detect, using an
internal status bit, when the charger is powered. Therefore when the charger supply is not connected to VDD_CHG,
the terminal must be left open-circuit. The VDD_CHG pin when not connected must be allowed to float and not pulled
to a power rail. When the battery charger is not enabled this pin may float to a low undefined voltage. Any DC
connection increases current consumption of the device. Capacitive components may be connected such as diodes,
FETs and ESD protection.
The battery charger is designed to operate with a permanently connected battery. If the application enables the
charger input to be connected while the battery is disconnected, then the BAT_P pin voltage may become unstable.
This in turn may cause damage to the internal switch-mode regulator. Connecting a 470µF capacitor to BAT_P limits
these oscillations so preventing damage.
Power Control and Regulation
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11.9 LED Drivers
BlueCore5‑Multimedia Flash includes two pads dedicated to driving LED indicators. Both terminals may be controlled
by firmware, while LED[0] can also be set by the battery charger.
The terminals are open-drain outputs, so the LED must be connected from a positive supply rail to the pad in series
with a current limiting resistor.
It is recommended that the LED pad (LED[0] or LED[1] pins) are operated with a pad voltage below 0.5V. In this
case the pad can be thought of as a resistor, R
ON
. The resistance together with the external series resistor sets the
current, I
LED
, in the LED. The current is also dependent on the external voltage, VDD, shown in Figure 11.2.
LED Forward Voltage, V
F
Pad Voltage, V
PAD
; R
ON
= 20Ω
R
LED
LED0 or LED1
Resistor Voltage Drop, V
R
VDD
I
LED
Figure 11.2: LED Equivalent Circuit
From Figure 11.2 it is possible to derive Equation 11.1 to calculate I
LED
or if a known value of current is required
through the LED, to give a specific luminous intensity, then the value of R
LED
could be calculated.
I
LED
=
VDD VF
RLED +R
ON
Equation 11.1: LED Current
For LED[0] or LED[1] pad to act as resistance, the external series resistor, R
LED
, needs to be such that the voltage
drop across it, V
R
, keeps V
PAD
below 0.5V. Therefore Equation 11.2 also applies.
VDD = V
F
+V
R
+V
PAD
Equation 11.2: LED PAD Voltage
Note:
The LED current will add to the overall application current, so conservative selection of the LEDs will preserve
power consumption.
Power Control and Regulation
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11.10 Reset (RST#)
BlueCore5‑Multimedia Flash can be reset from several sources:
RST# pin
Power-on reset
UART break character
Software configured watchdog timer
The RST# pin is an active low reset and is internally filtered using the internal low frequency clock oscillator. A reset
is performed between 1.5 and 4.0ms following RST# being active. CSR recommends that RST# be applied for a
period greater than 5ms.
The power-on reset typically occurs when the VDD_CORE supply falls below 1.26V and is released when
VDD_CORE rises above typically 1.31V. At reset the digital I/O pins are set to inputs for bi-directional pins and
outputs are tri-state. Following a reset, BlueCore5‑Multimedia Flash assumes the maximum XTAL_IN frequency,
which ensures that the internal clocks run at a safe (low) frequency until BlueCore5‑Multimedia Flash is configured
for the actual XTAL_IN frequency. If no clock is present at XTAL_IN, the oscillator in BlueCore5‑Multimedia Flash
free runs, again at a safe frequency.
11.10.1 Digital Pin States on Reset
Table 11.2 shows the pin states of BlueCore5‑Multimedia Flash on reset. Pull-up (PU) and pull-down (PD) default
to weak values unless specified otherwise.
Pin Name / Group I/O Type No Core Voltage
Reset Full Chip Reset
USB_DP Digital bi-directional N/a N/a
USB_DN Digital bi-directional N/a N/a
UART_RX Digital input with PD PD PD
UART_CTS Digital input with PD PD PD
UART_TX Digital bi-directional with PU PU PU
UART_RTS Digital bi-directional with PU PU PU
SPI_MOSI Digital input with PD PD PD
SPI_CLK Digital input with PD PD PD
SPI_CS# Digital input with PU PU PU
SPI_MISO Digital tri-state output with PD PD PD
PCM_IN Digital input with PD PD PD
Power Control and Regulation
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Pin Name / Group I/O Type No Core Voltage
Reset Full Chip Reset
PCM_CLK Digital bi-directional with PD PD PD
PCM_SYNC Digital bi-directional with PD PD PD
PCM_OUT Digital tri-state output with PD PD PD
RST# Digital input with PU PU PU
TEST_EN Digital input with PD PD PD
PIO[0:15] Digital bi-directional with PU/
PD PD PD
Table 11.2: Pin States on Reset
11.10.2 Status after Reset
The chip status after a reset is as follows:
Warm reset: data rate and RAM data remain available
Cold reset: data rate and RAM data not available
Power Control and Regulation
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12 Example Application Schematic
15n
L2
1V5
1V5 1V5 1V51V5_AUDIO
VDD_PIO
WS
SD_IN
SD_OUT
SCK
SPI_CLK
SPI_MISO
SPI_MOSI
SPI_CSB
UART_RX
UART_TX
MIC_BIAS
RST#
RF_N
RF_P
AUDIO_DCPL
ANT1
1V8
VDD_USB
1V8
3V3
3V3 3V3
TP4
TP5
TP6
TP7
VBAT
22u
L1
1V8
3V3
LX
TP3
TP2
CONNECT ALL AT STAR POINT TO
1V8
1V8
S1
PLAY
S2
REV
S3
FF
TP10
TP9
TP8
Printed Antenna
TP11
DBF81F104
UNBAL
1
NC
3
DC
2
GND
5
GND
8
GND
7
BAL 6
BAL 4
T1
SP2
16/32 Ohms
MIC2
SP1
16/32 Ohms
MIC1
10n
0402
C3
2u2
0402
C7
15p
0402
C2
15p
0402
C10
47n
0402
C14 1u
0402
C13
2u2
0402
C8
10n
0402
C4
2u2
0402
C9
10n
0402
C5
2R2
0402
R8
2k2
0402
R10 2k2
0402
R9
1u
0402
C15
1u
0402
C16
1u
0402
C17
1u
0402
C18
22n
0402
C12
2R2
0402
R72R2
0402
R6
2u2
0603
C11
4u7
0603
C6
I2S Interface
to Host
UART Interface
to Host
MCDSP
VDD_RADIO K1
VDD_ANA M1
VDD_CORE C13
VDD_PADS K13
XTAL_IN N1
VSS_DIG
K11
MIC_A_P
B2
MIC_B_N
A1
SPKR_A_P
D1
SPKR_B_N
B3
RST# G13
UART_TX L13
USB_DP
N13
SPI_CS# E13
SPI_CLK E11
PCM_OUT F11
PIO[2] E2
PIO[5] J11
PIO[8] J12
PIO[11] M10
VDD_LO L1
VDD_CORE J13
VDD_AUDIO B4
VDD_USB N10
VREGENABLE_L M3
LO_REF
N5
TEST_EN
G12
AIO[1]
M5
UART_RX M12
USB_DN
N12
SPI_MOSI F12
SPI_MISO E12
UART_CTS M13
PCM_IN F13
RXEN/PIO[0] E3
PIO[3] D3
PCM_SYNC G11
TXEN/PIO[1] F3
PIO[4] H12
PCM_CLK H11
PIO[9] L12
XTAL_OUT N2
PIO[10] L10
PIO[7] H13
VSS_DIG
C11
VSS_DIG
L11
VSS_AUDIO
C2
SPKR_A_N
D2
MIC_B_P
A2
MIC_A_N
B1
UART_RTS M11
PIO[6] M8
SPKR_B_P
A3
VSS_RADIO
H2
VSS_LO
L3
VSS_ANA
N4
VSS_AUDIO
C3
VSS_RADIO
G2
AUX_DAC
H3
VSS_RADIO
F2
N/C
F1 N/C
G1
RF_P
H1
PIO[15] N9
PIO[14] L9
PIO[13] M9
PIO[12] K12
RF_N
J1
VSS_LO
L2
VREGIN_L M2
AIO[0]
N6
LED0 D11
LED1 C8
LX A11
VREGOUT_H D13
VREGIN_AUDIO A4
VDD_CHG
B8
BAT_P
A13
VDD_SMP_CORE B13
VREGENABLE_H C7
VREGIN_H C12
VDD_PIO E1
AU_REF_DCPL
C1
MIC_BIAS
A5
VSS_DIG
G3
VSS_DIG
C6
VSS_DIG
N7
VSS_DIG
A9
VSS_DIG
A10
SUBS
N8 SUBS
L8 SUBS
M7 SUBS
L7 SUBS
B7 SUBS
A7 SUBS
M6 SUBS
L6 SUBS
B6 SUBS
A6 SUBS
L5 SUBS
C5 SUBS
B5 SUBS
M4 SUBS
L4 SUBS
K3 SUBS
J3 SUBS
K2
VDD_MEM A8
BAT_N
C10
VDD_MEM N11
Linear
for core
Switch mode
regulatorregulator Linear
Linear
for audio
regulator regulator
Enable
1.8V regulators1.5V regulators
Enable
(Input on
BAT_P)
VDD_CHG
B9
VDD_CHG
C9
BAT_P
A12
VSS_RADIO
J2
VSS_ANA
N3
VSS_AUDIO
C4
BAT_N
B10
VREGIN_H B12
VREGOUT_H D12
LX B11
U1
15nH
L3
15nH
L4
15p
0402
C19
15p
0402
C20
Phone main Li+ cell
BT1
RST#
p
in
to Host
Regulator enable pin
to Host
1
2 3
4
56
78
RN1
47k
Card Detect/Data Line[Bit3]
1
Command/Res
p
onse
2
Ground
3
Su
p
p
ly Volts
4
Clock
5
Ground
6
Data Line[Bit0]
7Data Line[Bit1]
8Data Line[Bit2]
9
Protection Detect NO SW Pin1
10
Protection Detect NO SW Pin2
11 Card Insert Detect NO SW Pin1
12
Card Insert Detect NO SW Pin2
13
CASE
14
CASE
15
J1
JAE SG5S009V1A1
3V3
3V3
SD CARD CONNECTOR
TP1
470k
0402
R3
470k
0402
R4
0R
0402
R5
10k
0402
R1
10k
0402
R2
100n
0402
C1
3V3 to
b
esu
p
p
lied externally
VDD_USB is between 1V8 and 3V3 typically
depending on host interface signal voltage on UART.
UART_RTS
UART_CTS
EXT_CLOCK
Main clock
from Host
CLOCK_REQ_IN
Clock request out
to Host
Clock request in
from Host
CLOCK_REQ_OUT
Any voltage a
b
ove 1.8V is to
b
esu
p
p
lied externally.
VDD_PIO is
b
etween 1V8 and 3V3 ty
p
ically
de
p
ending on host interface signal voltage on clock request lines.
Any voltage a
b
ove 1.8V is to
b
esu
p
p
lied externally.
TP12 TP13
(Venable,high >= 0.95V)
TP14
Figure 12.1: Example Application Schematic for BlueCore5‑Multimedia Flash
Example Application Schematic
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13 Electrical Characteristics
13.1 Absolute Maximum Ratings
Rating Min Max Unit
Storage Temperature -40 105 °C
Core Supply
Voltage
VDD_ANA, VDD_AUDIO, VDD_CORE,
VDD_LO and VDD_RADIO -0.4 1.65 V
I/O Voltage
VDD_PADS, VDD_PIO and VDD_USB -0.4 3.6 V
VDD_MEM -0.4 1.95 V
Supply Voltage
VREGIN_L and VREGIN_AUDIO -0.4 2.7 V
VREGIN_H, VREGENABLE_H and
VREGENABLE_L -0.4 4.9 V
BAT_P -0.4 4.4 V
LED[0] and LED[1] -0.4 4.4 V
VDD_CHG -0.4 6.5 V
Other Terminal Voltages VSS-0.4 VDD+0.4 V
13.2 Recommended Operating Conditions
Operating Condition Min Typ Max Unit
Operating Temperature Range
(a)
-40 20 85 °C
Core Supply
Voltage
VDD_ANA,
VDD_AUDIO,
VDD_CORE, VDD_LO
and VDD_RADIO
1.42 1.50 1.57 V
I/O Supply
Voltage
VDD_PADS, VDD_PIO
and VDD_USB 1.70 3.30 3.60 V
VDD_MEM 1.70 1.80 1.95 V
(a)
For radio performance over temperature refer to
BlueCore5‑Multimedia Flash Performance Specification
.
Electrical Characteristics
CS-113071-DSP2
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13.3 Input/Output Terminal Characteristics
Note:
For all I/O Terminal Characteristics:
VDD_ANA, VDD_AUDIO, VDD_CORE, VDD_LO and VDD_RADIO at 1.50V unless shown otherwise.
VDD_PADS, VDD_PIO and VDD_USB at 3.3V unless shown otherwise.
Current drawn into a pin is defined as positive; current supplied out of a pin is defined as negative.
13.3.1 High-voltage Linear Regulator
Normal Operation Min Typ Max Unit
Input voltage 2.7 -5.5
(a)
V
Output voltage (I
load
= 100mA / VREGIN_H = 3.0V) 1.70 1.80 1.95 V
Temperature coefficient -300 0300 ppm/°C
Output Noise
(b)
(c)
- - 1 mV rms
Load regulation (100µA < I
load
< 200mA ), ΔV
out
- - 5 mV
Settling time
(b)
(d)
- - 50 μs
Maximum output current 200 - - mA
Minimum load current 5 - - μA
Drop-out voltage ( I
load
= 200mA) - - 900 mV
Quiescent current (excluding Ioad, I
load
< 1mA) 30 50 60 μA
Low Power Mode
(e)
Quiescent current (excluding Ioad, I
load
< 100μA) 11 15 21 μA
(a)
Short-term operation up to 5.5V is permissible without damage and without the output voltage rising sufficiently to damage the rest of
BlueCore5‑Multimedia Flash, but output regulation and other specifications are no longer guaranteed at input voltages in excess of 4.9V.
5.5V can only be tolerated for short periods.
(b)
Regulator output connected to 47nF pure and 4.7μF 2.2Ω ESR capacitors.
(c)
Frequency range 100Hz - 100kHz.
(d)
10mA - 200mA pulsed load.
(e)
The regulator is in low power mode when the chip is in deep sleep mode, or in reset.
Electrical Characteristics
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13.3.2 Low-voltage Linear Regulator
Normal Operation Min Typ Max Unit
Input voltage 1.70 1.80 1.95 V
Output voltage (I
load
= 70mA / VREGIN_L = 1.7V) 1.42 1.50 1.57 V
Temperature coefficient -300 0300 ppm/°C
Output noise
(a)
(b)
- - 1 mV rms
Load regulation (100µA < I
load
< 90mA ), ΔV
out
- - 5 mV
Load regulation (100µA < I
load
< 115mA ), ΔV
out
- - 25 mV
Settling time
(a)
(c)
- - 50 μs
Maximum output current 115 - - mA
Minimum load current 5 - 100 μA
Drop-out voltage (I
load
= 115mA) - - 300 mV
Quiescent current (excluding Ioad, I
load
< 1mA) 50 90 150 μA
Low Power Mode
(d)
Quiescent current (excluding Ioad, I
load
< 100μA) 5 8 15 μA
(a)
Regulator output connected to 47nF pure and 4.7μF 2.2Ω ESR capacitors
(b)
Frequency range 100Hz to 100kHz
(c)
1mA to 115mA pulsed load
(d)
The regulator is in low power mode when the chip is in deep sleep mode, or in reset
Electrical Characteristics
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13.3.3 Low-voltage Linear Audio Regulator
Normal Operation Min Typ Max Unit
Input voltage 1.70 1.80 1.95 V
Output voltage (I
load
= 70mA / VREGIN_AUDIO = 1.7V) 1.42 1.50 1.57 V
Temperature coefficient -300 0300 ppm/°C
Output noise
(a)
(b)
- - 1 mV rms
Load regulation (100µA < I
load
< 70mA ), ΔV
out
- - 5 mV
Settling time
(a)
(c)
- - 50 μs
Maximum output current 70 - - mA
Minimum load current 5 - 100 μA
Dropout voltage (I
load
= 70mA) - - 300 mV
Quiescent current (excluding Ioad, I
load
< 1mA) 25 30 50 μA
Low Power Mode
(d)
Quiescent current (excluding Ioad, I
load
< 100μA) 5 8 15 μA
(a)
Regulator output connected to 47nF pure and 4.7μF 2.2Ω ESR capacitors
(b)
Frequency range 100Hz to 100kHz
(c)
1mA to 70mA pulsed load
(d)
The regulator is in low power mode when when no audio circuits are enabled
Electrical Characteristics
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13.3.4 Reset
Power-on Reset Min Typ Max Unit
VDD_CORE falling threshold 1.13 1.25 1.30 V
VDD_CORE rising threshold 1.20 1.30 1.35 V
Hysteresis 0.05 0.10 0.15 V
13.3.5 Regulator Enable
Switching Threshold Min Typ Max Unit
VREGENABLE_H
Rising threshold 0.50 -0.95 V
Falling threshold 0.35 -0.80 V
Hysteresis 0.14 -0.28 V
VREGENABLE_L
Rising threshold 0.50 -0.95 V
Falling threshold 0.35 -0.80 V
Hysteresis 0.14 -0.28 V
Electrical Characteristics
CS-113071-DSP2
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13.3.6 Switch-mode Regulator
Switch-mode Regulator Min Typ Max Unit
Input voltage 2.5 -4.4 V
Output voltage (I
load
= 70mA) 1.70 1.80 1.90 V
Temperature coefficient -250 -+250 ppm/°C
Normal Operation
Output ripple - - 10 mV rms
Transient settling time
(a)
- - 50 μs
Maximum load current 200 - - mA
Conversion efficiency (I
load
= 70mA) -90 - %
Switching frequency
(b)
-1.333 -MHz
Start-up current limit
(c)
30 50 80 mA
Low Power Mode
(d)
Output ripple - - 1 mV rms
Transient settling time
(e)
- - 700 μs
Maximum load current 5 - - mA
Minimum load current 1 - - μA
Conversion efficiency (I
load
= 1mA) -80 - %
Switching frequency
(f)
50 -150 kHz
(a)
For step changes in load of 30-80mA and 80-30mA.
(b)
Locked to crystal frequency.
(c)
Current is limited on start-up to prevent excessive stored energy in the filter inductor.
(d)
The regulator is in low power mode when the chip is in deep sleep mode, or in reset
(e)
100μA to 1mA pulsed load
(f)
Defines minimum period between pulses. Pulses are skipped at low current loads.
Note:
The external inductor used with the switch-mode regulator must have an ESR in the range 0.3 - 0.7Ω:
Low ESR < 0.3Ω causes instability.
High ESR > 0.7Ω derates the maximum current.
Electrical Characteristics
CS-113071-DSP2
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13.3.7 Battery Charger
Battery Charger Min Typ Max Unit
Input voltage 4.5 -6.5 V
Charging Mode (BAT_P rising to 4.2V)
Supply current
(a)
-4.5 6mA
Battery trickle charge current
(b)
(c)
Maximum setting (I-CTRL = 15) -14 -mA
Minimum setting (I-CTRL = 0) - 4 - mA
Maximum battery fast charge
current (I-CTRL = 15)
(c)
(d)
Headroom
(e)
> 0.7V 140- - mA
mAHeadroom = 0.3V -120 -
Minimum battery fast charge
current (I-CTRL = 0)
(c)
(d)
mAHeadroom > 0.7V -40 -
mAHeadroom = 0.3V -35 -
Fast charge step size
(I-CTRL = 0 to 15) Spread ±17% -6.3 -mA
Trickle charge voltage threshold -2.9 - V
Float voltage (with correct trim value set), V
FLOAT
(f)
4.17 4.2 4.23 V
Float voltage trim step size
(f)
-50 -mV
Battery charge termination current, % of fast charge current 510 20 %
Standby Mode (BAT_P falling from 4.2V)
Supply current
(a)
-1.5 2mA
Battery current --5 -μA
Battery recharge hysteresis
(g)
100 -200 mV
Shutdown Mode (VDD_CHG too low or disabled by firmware)
Electrical Characteristics
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Battery Charger Min Typ Max Unit
VDD_CHG under-voltage
threshold
VVDD_CHG rising -3.90 -
VVDD_CHG falling -3.70 -
VDD_CHG - BAT_P lockout
threshold
VVDD_CHG rising -0.22 -
VVDD_CHG falling -0.17 -
Supply current -1.5 2mA
Battery current -1 - 0 μA
(a)
Current into VDD_CHG - does not include current delivered to battery (I
VDD_CHG
- I
BAT_P
)
(b)
BAT_P < Float voltage
(c)
Charge current can be set in 16 equally spaced steps.
(d)
Trickle charge threshold < BAT_P < Float voltage
(e)
Where headroom = VDD_CHG - BAT_P
(f)
Float voltage can be adjusted in 15 steps. Trim setting is determined in production test and must be loaded into the battery charger by
firmware during boot-up sequence
(g)
Hysteresis of (V
FLOAT
- BAT_P) for charging to restart
Electrical Characteristics
CS-113071-DSP2
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13.3.8 Digital Terminals
Supply Voltage Levels Min Typ Max Unit
VDD
PRE
1.4Pre-driver supply voltage 1.5 1.6 V
VDD I/O supply
voltage (post-driver)
3.0Full spec. 3.3 3.6 V
1.7Reduced spec. -3.0 V
Input Voltage Levels
V
IL
input logic level low V-0.3 -0.25xVDD
V
IH
input logic level high V0.625xVDD -VDD+0.3
V
SCHMITT
Schmitt voltage V0.25xVDD -0.625xVDD
Output Voltage Levels
V
OL
output logic level low, l
OL
= 4.0mA V0 - 0.125
V
OH
output logic level high, l
OH
= -4.0mA V0.75xVDD -VDD
Input and Tri-state Currents
I
i
input leakage current at V
in
= VDD or 0V nA-100 0100
I
oz
tri-state output leakage current at V
o
= VDD or 0V nA-100 0100
With strong pull-up μA-100 -40 -10
With strong pull-down μA10 40 100
With weak pull-up μA-5 -1.0 -0.2
With weak pull-down μA-0.2 +1.0 5.0
C
I
Input Capacitance pF1.0 -5.0
Resistive Strength
R
puw
weak pull-up strength at VDD-0.2V Ω500k -2M
R
pdw
weak pull-down strength at 0.2V Ω500k -2M
R
pus
strong pull-up strength at VDD-0.2V Ω10k -50k
R
pds
strong pull-down strength at 0.2V Ω10k -50k
Electrical Characteristics
CS-113071-DSP2
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13.3.9 LED Driver Pads
LED Driver Pads Min Typ Max Unit
Off current - 1 2 µA
On resistance V
PAD
< 0.5V -20 33 Ω
On resistance, pad enabled by
battery charger V
PAD
< 0.5V -20 50 Ω
13.3.10 USB
USB Terminals Min Typ Max Unit
VDD_USB for correct USB operation 3.1 -3.6 V
Input Threshold
V
IL
input logic level low - - 0.3VDD_US
BV
V
IH
input logic level high 0.7VDD_US
B- - V
Input Leakage Current
VSS_DIG < V
IN
< VDD_USB
(a)
-1 1 5 μA
C
I
Input capacitance 2.5 -10.0 pF
Output Voltage Levels to Correctly Terminated USB Cable
V
OL
output logic level low 0.0 -0.2 V
V
OH
output logic level high 2.8 -VDD_USB V
(a)
Internal USB pull-up disabled
Electrical Characteristics
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13.3.11 Auxiliary ADC
Auxiliary ADC Min Typ Max Unit
Resolution - - 10 Bits
Input voltage range
(a)
0 - VDD_ANA V
Accuracy
(Guaranteed monotonic)
INL -1 - 1 LSB
DNL 0 - 1 LSB
Offset -1 - 1 LSB
Gain Error -0.8 -0.8 %
Input Bandwidth -100 -kHz
Conversion time -2.5 -µs
Sample rate
(b)
- - 700 Samples/
s
(a)
LSB size = VDD_ANA/1023
(b)
The auxilliary ADC is accessed through a VM function. The sample rate given is achieved as part of this function.
13.3.12 Auxiliary DAC
Auxiliary DAC Min Typ Max Unit
Resolution - - 8 Bits
Average output step size
(a)
12.5 14.5 17.0 mV
Output Voltage monotonic
(a)
Voltage range (I
O
= 0mA) VSS_DIG -VDD_PIO V
Current range -10.0 -0.1 mA
Minimum output voltage (I
O
=100μA) 0.0 -0.2 V
Maximum output voltage (I
O
=10mA) VDD_PIO-0.
3-VDD_PIO V
High Impedance leakage current -1 - 1 μA
Offset -220 -120 mV
Integral non-linearity
(a)
-2 - 2 LSB
Settling time (50pF load) - - 10 μs
(a)
Specified for an output voltage between 0.2V and VDD_PIO - 0.2V. Output is high impedance when chip is in Deep Sleep mode.
Electrical Characteristics
CS-113071-DSP2
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13.3.13 Clocks
Clock Source Min Typ Max Unit
Crystal Oscillator
Crystal frequency
(a)
16 26 26 MHz
Digital trim range
(b)
5.0 6.2 8.0 pF
Trim step size
(b)
-0.1 -pF
Transconductance 2.0 - - mS
Negative resistance
(c)
870 1500 2400 Ω
External Clock
Input frequency
(d)
12 26 52 MHz
Clock input level
(e)
0.4 -VDD_ANA V pk-pk
Edge jitter (allowable jitter), at zero crossing - - 15 ps rms
XTAL_IN input impedance -≥10 -
XTAL_IN input capacitance -≤4 -pF
(a)
Integer multiple of 250kHz
(b)
The difference between the internal capacitance at minimum and maximum settings of the internal digital trim.
(c)
XTAL frequency = 16MHz; XTAL C
0
= 0.75pF; XTAL load capacitance = 8.5pF.
(d)
Clock input can be any frequency between 12MHz to 52MHz in steps of 250kHz plus CDMA/3G TCXO frequencies of 14.40, 15.36, 16.2,
16.8, 19.2, 19.44, 19.68, 19.8 and 38.4MHz.
(e)
Clock input can be either sinusoidal or square wave. If the peaks of the signal are below VSS_ANA or above VDD_ANA. A DC blocking
capacitor is required between the signal and XTAL_IN.
Electrical Characteristics
CS-113071-DSP2
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13.3.14 Stereo CODEC: Analogue to Digital Converter
Analogue to Digital Converter
Parameter Conditions Min Typ Max Unit
Resolution - - - 16 Bits
Input Sample
Rate, F
sample
- 8 - 44.1 kHz
Signal to Noise
Ratio, SNR
(a)
f
in
= 1kHz
B/W = 20Hz→20kHz
A-Weighted
THD+N < 1%
150mV
pk-pk
input
F
sample
-8kHz 79 -dB
dB11.025kHz -77 -
dB16kHz -76 -
dB22.050kHz -76 -
dB32kHz -75 -
dB44.1kHz -75 -
Digital Gain Digital Gain Resolution = 1/32dB dB-24 -21.5
Analogue Gain Analogue Gain Resolution = 3dB dB-3 -3 42
Input full scale at maximum gain (differential) - 4 - mV rms
Input full scale at minimum gain (differential) mV rms-800 -
3dB Bandwidth kHz-20 -
Microphone mode input impedance Ω- 6.0 -
THD+N (microphone input) @ 30mV rms input %- 0.04 -
(a)
Improved SNR performance can be achieved at the expense of current consumption. See Optimising BlueCore5-Multimedia ADC
Performance Application Note for details.
Electrical Characteristics
CS-113071-DSP2
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13.3.15 Stereo CODEC: Digital to Analogue Converter
Digital to Analogue Converter
Parameter Conditions Min Typ Max Unit
Resolution - - - 16 Bits
Output Sample
Rate, F
sample
- 8 - 48 kHz
Signal to Noise
Ratio, SNR
f
in
= 1kHz
B/W = 20Hz→20kHz
A-Weighted
THD+N < 0.01%
0dBFS signal
Load = 100kΩ
F
sample
8kHz -95 -dB
11.025kHz -95 -dB
16kHz -95 -dB
22.050kHz -95 -dB
32kHz -95 -dB
44.1kHz -95 -dB
48kHz -95 -dB
Digital Gain Digital Gain Resolution = 1/32dB -24 -21.5 dB
Analogue Gain Analogue Gain Resolution = 3dB 0 - -21 dB
Output voltage full scale swing (differential) -750 -mV rms
Allowed Load
Resistive 16(8) -OC Ω
Capacitive - - 500 pF
THD+N 100kΩ load - - 0.01 %
THD+N 16Ω load - - 0.1 %
SNR (Load = 16Ω, 0dBFS input relative to digital silence) -95 -dB
Electrical Characteristics
CS-113071-DSP2
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14 Power Consumption
Role Connection Audio Packet Type Description
Current
UnitVREGIN_L = 1.8V VREGIN_H = 3.2V VDD_CHG = 3.6V
16MHz 32MHz 16MHz 32MHz 16MHz 32MHz
Stand-by Host connection 0.07 0.08 0.08 0.09 0.06 0.07 mA
Page Scan Interval = 1280ms 0.46 0.47 0.51 0.51 0.31 0.32 mA
Inquiry and Page Scan Inquiry scan = 1280ms
Page scan = 1280ms 0.92 0.88 0.92 0.91 0.51 0.54 mA
Master ACL No traffic 4.2 4.2 4.2 4.3 2.6 2.7 mA
Master ACL File transfer TX 8.9 9.1 8.9 9.1 5.1 5.2 mA
Master ACL Sniff = 40ms 1.8 1.8 1.8 1.8 1.1 1.1 mA
Master ACL Sniff = 1280ms 0.21 0.20 0.23 0.21 0.15 0.14 mA
Master eSCO EV3 21 22 22 23 12 12 mA
Master eSCO EV3 Setting S1 23 23 24 24 13 13 mA
Master eSCO 2 EV3 Setting S2 22 22 22 22 12 12 mA
Master eSCO 2 EV3 Setting S3 16 17 17 17 9.0 9.1 mA
Master eSCO EV5 16 16 16 16 8.8 8.9 mA
Master SCO HV1 39 41 39 42 22 23 mA
Master SCO HV3 21 22 21 23 12 12 mA
Power Consumption
CS-113071-DSP2
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Role Connection Audio Packet Type Description
Current
UnitVREGIN_L = 1.8V VREGIN_H = 3.2V VDD_CHG = 3.6V
16MHz 32MHz 16MHz 32MHz 16MHz 32MHz
Master SCO HV3 Sniff = 30ms 21 22 21 22 12 12 mA
Slave ACL No Traffic 15 15 15 16 8.2 8.2 mA
Slave ACL File transfer RX 20 18 20 18 10 9.44 mA
Slave ACL Sniff = 40ms 1.5 1.6 1.5 1.7 0.96 1.0 mA
Slave ACL Sniff = 1280ms 0.27 0.27 0.28 0.28 0.18 0.18 mA
Slave eSCO EV3 25 25 25 25 13 14 mA
Slave eSCO EV3 Setting S1 27 28 27 27 14 15 mA
Slave eSCO 2 EV3 Setting S2 26 26 26 26 14 15 mA
Slave eSCO 2 EV3 Setting S3 23 24 23 24 13 13 mA
Slave eSCO EV5 21 22 22 22 12 12 mA
Slave SCO HV1 39 41 40 42 22 23 mA
Slave SCO HV3 27 28 27 28 14 15 mA
Slave SCO HV3 Sniff = 30ms 21 21 22 22 11 12 mA
Power Consumption
CS-113071-DSP2
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14.1 Kalimba DSP and CODEC Typical Average Current Consumption
DSP Average Unit
DSP core (including PM memory access)
Minimum (NOP) 0.11 mA/MIPS
Maximum (MAC) 0.32 mA/MIPS
DSP memory access (DM1 or DM2) 0.08 mA/MIPS
14.2 Typical Peak Current at 20°C
Device Activity / State Typ Unit
Peak current during cold boot 45 mA
Master TX peak current 45 mA
Master RX peak current 45 mA
Slave TX peak current 45 mA
Slave RX peak current 45 mA
14.3 Conditions
Host interface = UART
Baud rate = 115200
Supply = 1.8V in to VREGIN_L and VREGIN_AUDIO
AFH switched OFF
No audio load
RF Output power = 0dBm
VM OFF
eSCO settings:
EV3 and EV5 = no retry
Setting S1 = optimised for power consumption
Firmware build ID = 4508
Power Consumption
CS-113071-DSP2
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15 RoHS Statement with a List of Banned Materials
15.1 RoHS Statement
BlueCore5‑Multimedia Flash where explicitly stated in this Data Sheet meets the requirements of Directive 2002/95/
EC of the European Parliament and of the Council on the
Restriction of Hazardous Substance
(RoHS).
15.1.1 List of Banned Materials
The following banned substances are not present in BlueCore5‑Multimedia Flash which is compliant with RoHS:
Cadmium
Lead
Mercury
Hexavalent chromium
PBB (Polybrominated Bi-Phenyl)
PBDE (Polybrominated Diphenyl Ether)
In addition, BlueCore5‑Multimedia Flash is free from the following substances:
PVC (Poly Vinyl Chloride)
RoHS Statement with a List of Banned Materials
CS-113071-DSP2
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16 CSR Bluetooth Software Stack
BlueCore5‑Multimedia Flash is supplied with Bluetooth v2.1 + EDR specification compliant stack firmware, which
runs on the internal RISC microcontroller.
The BlueCore5‑Multimedia Flash software architecture allows Bluetooth processing and the application program to
be shared in different ways between the internal RISC microcontroller and an external host processor (if any). The
upper layers of the Bluetooth stack, above the
Host Controller Interface
(HCI), can be run either on-chip or on the
host processor.
16.1 BlueCore HCI Stack
HCI
LM
LC
Program Memory
48KBytes RAM Bluetooth Stack
MCU
Host I/O
Radio
Digital Audio
Host
Analogue Audio
2
Microphone or Speaker
USB
UART
PCM / SPDIF / I
2
S
Figure 16.1: BlueCore HCI Stack
Note:
Program Memory in Figure 16.1 is internal Flash.
In the implementation shown in Section 16.1 the internal processor runs the Bluetooth stack up to the HCI. The Host
processor must provide all upper layers including the application.
16.1.1 Key Features of the HCI Stack: Standard Bluetooth Functionality
CSR supports the following Bluetooth v2.1 + EDR specification functionality:
Secure simple pairing
Sniff subrating
Encryption pause resume
Packet boundary flags
Encryption
Extended inquiry response
As well as the following mandatory functions of Bluetooth v2.0 + EDR specification:
Adaptive frequency hopping
(AFH), including classifier
Faster connection - enhanced inquiry scan (immediate FHS response)
LMP improvements
Parameter ranges
And optional Bluetooth v2.0 + EDR specification functionality:
CSR Bluetooth Software Stack
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AFH as Master and Automatic Channel Classification
Fast Connect - Interlaced Inquiry and Page Scan plus RSSI during Inquiry
Extended SCO
(eSCO), eV3 +CRC, eV4, eV5
SCO handle
Synchronisation
The firmware was written against the Bluetooth v2.1 + EDR specification:
Bluetooth components:
Baseband (including LC)
LM
HCI
Standard UART HCI Transport Layers
All standard Bluetooth radio packet types
Full Bluetooth data rate, enhanced data rates of 2 and 3Mbps
Operation with up to seven active slaves
2
Scatternet v2.5 operation
Maximum number of simultaneous active ACL connections: 7
Maximum number of simultaneous active SCO connections: 3
3
Operation with up to three SCO links, routed to one or more slaves
All standard SCO voice coding, plus transparent SCO
Standard operating modes: Page, Inquiry, Page-Scan and Inquiry-Scan
All standard pairing, authentication, link key and encryption operations
Standard Bluetooth power saving mechanisms: Hold, Sniff and Park modes, including Forced Hold
Dynamic control of peers' transmit power via LMP
Master/Slave switch
Broadcast
Channel quality driven data rate
All standard Bluetooth test modes
2
This is the maximum allowed by Bluetooth v2.1 + EDR specification.
3
BlueCore5‑Multimedia Flash supports all combinations of active ACL and SCO channels for both master
and slave operation, as specified by the Bluetooth v2.1 + EDR specification.
CSR Bluetooth Software Stack
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16.1.2 Key Features of the HCI Stack: Extra Functionality
The firmware extends the standard Bluetooth functionality with the following features:
Supports
BlueCore Serial Protocol
(BCSP), a proprietary, reliable alternative to the standard Bluetooth
UART Host Transport
Supports
H4 Deep Sleep
(H4DS), a proprietary alternative to the standard Bluetooth UART Host Transport,
supporting Deep Sleep for low-power applications
Provides a set of approximately 50 manufacturer-specific HCI extension commands. This command set,
called
BlueCore Command
(BCCMD), provides:
Access to BlueCore5‑Multimedia Flash general-purpose PIO port
The negotiated effective encryption key length on established Bluetooth links
Access to the firmware random number generator
Controls to set the default and maximum transmit powers; these can help minimise interference
between overlapping, fixed-location piconets
Dynamic UART configuration
Bluetooth radio transmitter enable/disable. A simple command connects to a dedicated hardware
switch that determines whether the radio can transmit.
The firmware can read the voltage on a pair of BlueCore5‑Multimedia Flash external pins. This is normally
used to build a battery monitor
A block of BCCMD commands provides access to the BlueCore5‑Multimedia Flash
Persistent Store
(PS)
configuration database . The database sets the BlueCore5‑Multimedia Flash Bluetooth address, Class of
Device, Bluetooth radio (transmit class) configuration, SCO routing,
link manager
(LM), etc.
A UART break condition can be used in three ways:
Presenting a UART break condition to the chip can force the chip to perform a hardware reboot
Presenting a break condition at boot time can hold the chip in a low power state, preventing normal
initialisation while the condition exists
With BCSP, the firmware can be configured to send a break to the host before sending data. (This is
normally used to wake the host from a Deep Sleep state.)
A block of Bluetooth radio test or BIST commands allows direct control of the BlueCore5‑Multimedia Flash
radio. This aids the development of modules' radio designs, and can be used to support Bluetooth
qualification.
Hardware low power modes: Shallow Sleep and Deep Sleep. The chip drops into modes that significantly
reduce power consumption when the software goes idle.
SCO channels are normally routed via HCI (over BCSP). However, up to three SCO channels can be routed
over the PCM interface (at the same time as routing any remaining SCO channels over HCI).
Note:
Always refer to the Firmware Release Note for the specific functionality of a particular build.
16.2 Host-Side Software
BlueCore5‑Multimedia Flash can be ordered with companion host-side software:
BlueCore5-PC includes software for a full Windows 98/ME, Windows 2000 or Windows XP Bluetooth host-
side stack together with IC hardware described in this document.
BlueCore5-Mobile includes software for a full host-side stack designed for modern ARM chip-based mobile
handsets together with IC hardware described in this document.
16.3 eXtension
A wide range of software options is available from 3rd parties through the CSR eXtension partner program, see
http://www.csr.com/eXtension.
CSR Bluetooth Software Stack
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17 Ordering Information
Interface Version
Package
Order Number
Type Size Shipment
Method
UART and USB LFBGA 120-ball
(Pb free)
7 x 7 x 1.3mm,
0.5mm pitch Tape and reel BC57H687C-ITM-E4
(a)
(a)
Until BC57H687C reaches Production status, engineering samples order number applies. This is BC57H687C-ES-ITM-E, with no minimum
order quantity.
Note:
At Production status Minimum Order Quantity is 2kpcs taped and reeled.
To contact a CSR representative, email sales@csr.com or go to www.csr.com/contacts
17.1 Tape and Reel Information
For tape and reel packing and labelling see
IC Packing and Labelling Specification
.
17.2 Moisture Sensitivity Level (MSL)
BlueCore5‑Multimedia Flash is qualified to MSL3 in accordance with JEDEC J-STD-020.
Ordering Information
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18 Document References
Document Reference, Date
Core Specification of the Bluetooth System
v2.1 + EDR, 26 July 2007
Test Suite Structure (TSS) and Test Purposes (TP)
System Specification 1.2/2.0/2.0 + EDR/ 2.1/2.1 + EDR
RF.TS/2.1.E.0, 27 December 2006
Universal Serial Bus Specification
v2.0, 27 April 2000
Selection of I
2
C EEPROMS for Use with BlueCore
bcore-an-008P, 30 September 2003
IC Packing and Labelling Specification
CS-112584-SPP, January 2007
Moisture / Reflow Sensitivity Classification for
Nonhermitic Solid State Surface Mount Devices
IPC / JEDEC J-STD-020
Electrostatic Discharge (ESD) Sensitivity Testing
Human Body Model (HBM)
JESD22-A114
BlueCore
®
5‑Multimedia Flash Performance
Specification
CS-116862-SPP, 2008
BlueCore5 Charger Description and Calibration
Procedure Application Note
CS-113282-ANP, 2007
BlueCore5-Multimedia External Recommendations for
ESD Protection
CS-114058-ANP, 2007
Typical Solder Reflow Profile for Lead-free Device
CS-116434-ANP, 2007
Bluetooth and IEEE 802.11 b/g Co-existence Solutions
Overview
bcore-an-066P, May 2005
Optimising BlueCore5-Multimedia ADC Performance
Application Note
CS-120059-AN, 2008
Document References
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Terms and Definitions
Term Definition
3G 3rd Generation of multimedia
802.11 WLAN specification defined by a working group within the IEEE
ADC Analogue to Digital Converter
AFH Adaptive Frequency Hopping
AGC Automatic Gain Control
BCCMD BlueCore Command
BCSP BlueCore Serial Protocol
BGA Ball Grid Array
BIST Built-In Self Test
BlueCore
®
Group term for CSR’s range of Bluetooth wireless technology chips
Bluetooth
®
Set of technologies providing audio and data transfer over short-range radio connections
BMC Burst Mode Controller
CDMA Code Division Multiple Access
CODEC COder DECoder
CRC Cyclic Redundancy Check
CSR Cambridge Silicon Radio
CVSD Continuous Variable Slope Delta Modulation
DAC Digital to Analogue Converter or Device Access Code
dBm Decibels relative to 1mW
DC Direct Current
DDS Direct Digital Synthesis
DSP Digital Signal Processor
EDR Enhanced Data Rate
eSCO Extended SCO
ESR Equivalent Series Resistance
FHS Frequency Hop Synchronisation
GCI General Circuit Interface
GFSK Gaussian Frequency Shift Keying
GSM Global System for Mobile communications
H4DS H4 Deep Sleep
HCI Host Controller Interface
IIR Infinite Impulse Response (filter)
I/O Input/Output
I
2
CInter-Integrated Circuit
I
2
SInter-Integrated Circuit Sound
IC Integrated Circuit
IEEE Institute of Electronic and Electrical Engineers
IF Intermediate Frequency
LCD Liquid-Crystal Display
LED Light Emitting Diode
LJ Left-Justified
Terms and Definitions
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Term Definition
LM Link Manager
LMP Link Manager Protocol
LNA Low Noise Amplifier
LSB Least-Significant Bit
MAC Medium Access Control
MCU Micro Controller Unit
MIPS Million Instructions Per Second
MMU Memory Management Unit
NSMD Non Solder Mask Defined
PA Power Amplifier
PCB Printed Circuit Board
PCM Pulse Code Modulation
PIO Programmable Input Output
PS Persistent Store
PS Key Persistent Store Key
RAM Random Access Memory
RF Radio Frequency
RISC Reduced Instruction Set Computer
RJ Right-Justified
RoHS The Restriction of Hazardous Substances in Electrical and Electronic Equipment Directive
(2002/95/EC)
RSSI Received Signal Strength Indication
SBC Sub-band Coding
SCO Synchronous Connection-Oriented
SNR Signal-to-Noise Ratio
SPI Serial Peripheral Interface
SPDIF Sony/Philips Digital InterFace (also IEC 958 type II, part of IEC-60958). An interface designed
to transfer stereo digital audio signals between various devices and stereo components with
minimal loss.
TCXO Temperature Compensated crystal Oscillator
UART Universal Asynchronous Receiver Transmitter
USB Universal Serial Bus
VCO Voltage Controlled Oscillator
VM Virtual Machine
VoIP Voice over Internet Protocol
W-CDMA Wideband Code Division Multiple Access
WCS Wireless Co-existence System
Wi-Fi
®
Wireless Fidelity (IEEE 802.11x wireless networking)
Terms and Definitions
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