Copyright © Bridgetek Pte Ltd 1
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Bridgetek Pte Ltd
FT81x
(Advanced Embedded Video Engine)
The FT81x is a series of easy to use graphic
controllers targeted at embedded applications to
generate high-quality Human Machine Interfaces
(HMIs). It has the following features:
Advanced Embedded Video Engine(EVE) with
high resolution graphics and video playback
FT81x functionality includes graphic control,
audio control, and touch control interface.
Pinout backward compatible with FT800
(FT810) and FT801 (FT811).
Support multiple widgets for simplified design
implementation
Built-in graphics operations allow users with
little expertise to create high-quality displays
Support 4-wire resistive touch screen
(FT810/FT812)
Support capacitive touch screen with up to 5
touches detection (FT811/FT813)
Hardware engine can recognize touch tags and
track touch movement. Provides notification for
up to 255 touch tags.
Enhanced sketch processing
Programmable interrupt controller provides
interrupts to host MCU
Built-in 12MHz crystal oscillator with PLL
providing programmable system clock up to
60MHz
Clock switch command for internal or external
clock source. External 12MHz crystal or clock
input can be used for higher accuracy.
Video RGB parallel output; configurable to
support PCLK up to 60MHz and R/G/B output of
1 to 8 bits
Programmable timing to adjust HSYNC and
VSYNC timing, enabling interface to numerous
displays
Support for LCD display with resolution up to
SVGA (800x600) and formats with data enable
(DE) mode or VSYNC/HSYNC mode
Support landscape and portrait orientations
Display enable control output to LCD panel
Integrated 1MByte graphics RAM, no frame
buffer RAM required
Support playback of motion-JPEG encoded AVI
videos
Mono audio channel output with PWM output
Built-in sound synthesizer
Audio wave playback for mono 8-bit linear PCM,
4-bit ADPCM and µ-Law coding format at
sampling frequencies from 8 kHz to 48 kHz.
Built-in digital filter reduces the system design
complexity of external filtering
PWM output for display backlight dimming
control
Advanced object oriented architecture enables
low cost MPU/MCU as system host using SPI
interfaces
Support SPI data lines in single, dual or quad
mode; SPI clock up to 30MHz
Power mode control allows the chip to be put in
power down, sleep and standby states
Supports I/O voltage from 1.8V to 3.3V
Internal voltage regulator supplies 1.2V to the
digital core
Build-in Power-on-reset circuit
-40°C to 85°C extended operating temperature
range
Available in a compact Pb-free, VQFN-48 and
VQFN-56 package, RoHS compliant
Neither the whole nor any part of the information contained in, or the product described in this manual, may be adapted or
reproduced in any material or electronic form without the prior written consent of the copyright holder. This product and its
documentation are supplied on an as-is basis and no warranty as to their suitability for any particular purpose is either made or
implied. Bridgetek Pte Ltd will not accept any claim for damages howsoever arising as a result of use or failure of this product.
Your statutory rights are not affected. This product or any variant of it is not intended for use in any medical appliance, device or
system in which the failure of the product might reasonably be expected to result in personal injury. This document provides
preliminary information that may be subject to change without notice. No freedom to use patents or other intellectual property
rights is implied by the publication of this document. Bridgetek Pte Ltd, 178 Paya Lebar Road, #07-03, Singapore 409030.
Singapore Registered Company Number: 201542387H
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FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
1 Typical Applications
Point of Sales Machines
Multi-function Printers
Instrumentation
Home Security Systems
Graphic touch pad – remote, dial pad
Tele / Video Conference Systems
Phones and Switchboards
Medical Appliances
Blood Pressure displays
Heart monitors
Glucose level displays
Breathalyzers
Gas chromatographs
Power meter
Home appliance devices
Set-top box
Thermostats
Sprinkler system displays
Medical Appliances
GPS / Satnav
Vending Machine Control Panels
Elevator Controls
……and many more
1.1 Part Numbers
Part Number
Description
Package
FT810Q-x
EVE with 18 bit RGB, resistive touch
48 Pin VQFN, body 7 x 7 mm, pitch 0.5mm
FT811Q-x
EVE with 18 bit RGB, capacitive touch
48 Pin VQFN, body 7 x 7 mm, pitch 0.5mm
FT812Q-x
EVE with 24 bit RGB, resistive touch
56 Pin VQFN, body 8 x 8 mm, pitch 0.5mm
FT813Q-x
EVE with 24 bit RGB, capacitive touch
56 Pin VQFN, body 8 x 8 mm, pitch 0.5mm
Table 1- FT81x Embedded Video Engine Part Numbers
Note: Packaging codes for x is:
-R: Taped and Reel (3000pcs per reel)
-T: Tray packing (260 pcs per tray for VQFN-48, 348 pcs per tray for VQFN-56)
For example: FT810Q-R is 3000 VQFN pieces in taped and reel packaging
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FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
2 Block Diagram
Figure 2-1 FT81x Block Diagram
For a description of each function please refer to Section 4.
Figure 2-2 FT81x System Design Diagram
FT81x with EVE (Embedded Video Engine) technology simplifies the system architecture for advanced
human machine interfaces (HMIs) by providing support for display, audio, and touch as well as an object
oriented architecture approach that extends from display creation to the rendering of the graphics.
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FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Table of Contents
1 Typical Applications ....................................................... 2
1.1 Part Numbers ............................................................................. 2
2 Block Diagram ............................................................... 3
3 Device Pin Out and Signal Description ........................... 7
3.1 FT810 VQFN-48 Package Pin Out ............................................... 7
3.2 FT811 VQFN-48 Package Pin Out ............................................... 7
3.3 FT812 VQFN-56 Package Pin Out ............................................... 8
3.4 FT813 VQFN-56 Package Pin Out ............................................... 8
3.5 Pin Description .......................................................................... 9
4 Function Description ................................................... 13
4.1 Quad SPI Host Interface .......................................................... 13
4.1.1 QSPI Interface .......................................................................................... 13
4.1.2 Serial Data Protocol ................................................................................... 15
4.1.3 Host Memory Read .................................................................................... 15
4.1.4 Host Memory Write.................................................................................... 16
4.1.5 Host Command ......................................................................................... 16
4.1.6 Interrupts ................................................................................................ 20
4.2 System Clock ........................................................................... 20
4.2.1 Clock Source ............................................................................................ 20
4.2.2 Phase Locked Loop .................................................................................... 21
4.2.3 Clock Enable ............................................................................................. 21
4.2.4 Clock Frequency ........................................................................................ 22
4.3 Graphics Engine ....................................................................... 22
4.3.1 Introduction ............................................................................................. 22
4.3.2 ROM and RAM Fonts .................................................................................. 23
4.4 Parallel RGB Interface ............................................................. 26
4.5 Miscellaneous Control .............................................................. 29
4.5.1 Backlight Control Pin ................................................................................. 29
4.5.2 DISP Control Pin ....................................................................................... 29
4.5.3 General Purpose IO pins ............................................................................ 29
4.5.4 Pins Drive Current Control .......................................................................... 30
4.6 Audio Engine ............................................................................ 30
4.6.1 Sound Synthesizer .................................................................................... 30
4.6.2 Audio Playback ......................................................................................... 32
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FT81X Embedded Video Engine Datasheet
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4.7 Touch-Screen Engine ............................................................... 33
4.7.1 Resistive Touch Control .............................................................................. 33
4.7.2 Capacitive Touch Control ............................................................................ 34
4.7.3 Compatibility mode ................................................................................... 35
4.7.4 Extended mode ......................................................................................... 35
4.7.5 Short-circuit protection .............................................................................. 35
4.7.6 Capacitive touch configuration .................................................................... 35
4.7.7 Touch detection in none-ACTIVE state ......................................................... 36
4.8 Power Management ................................................................. 36
4.8.1 Power supply ............................................................................................ 36
4.8.2 Internal Regulator and POR ........................................................................ 36
4.8.3 Power Modes ............................................................................................ 37
4.8.4 Reset and boot-up sequence ....................................................................... 39
4.8.5 Pin Status at Different Power States ............................................................ 39
5 Memory Map ................................................................ 41
5.1 Registers.................................................................................. 41
5.2 Chip ID ..................................................................................... 46
6 Devices Characteristics and Ratings ............................ 47
6.1 Absolute Maximum Ratings ...................................................... 47
6.2 ESD and Latch-up Specifications .............................................. 47
6.3 DC Characteristics .................................................................... 47
6.4 AC Characteristics .................................................................... 50
6.4.1 System clock and reset .............................................................................. 50
6.4.2 SPI interface timing ................................................................................... 50
6.4.3 RGB Interface Timing ................................................................................ 51
7 Application Examples .................................................. 53
8 Package Parameters .................................................... 55
8.1 Part Markings .......................................................................... 55
8.1.1 Top side ........................................................................................................ 55
8.1.3 Bottom Side .................................................................................................. 55
8.2 VQFN-48 Package Dimensions ................................................. 56
8.3 VQFN-56 Package Dimensions ................................................. 56
8.4 Solder Reflow Profile ............................................................... 56
9 Contact Information .................................................... 58
Appendix A – References ................................................... 59
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FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Document References ...................................................................... 59
Acronyms and Abbreviations ............................................................ 59
Appendix B - List of Figures and Tables ............................. 61
List of Figures .................................................................................. 61
List of Tables .................................................................................... 61
Appendix C - Revision History ............................................ 63
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FT81X Embedded Video Engine Datasheet
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3 Device Pin Out and Signal Description
3.1 FT810 VQFN-48 Package Pin Out
Figure 3-1 Pin Configuration FT810 VQFN-48 (top view)
3.2 FT811 VQFN-48 Package Pin Out
Figure 3-1 Pin Configuration FT811 VQFN-48 (top view)
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FT81X Embedded Video Engine Datasheet
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3.3 FT812 VQFN-56 Package Pin Out
Figure 3-1 Pin Configuration FT812 VQFN-56 (top view)
3.4 FT813 VQFN-56 Package Pin Out
Figure 3-1 Pin Configuration FT813 VQFN-56 (top view)
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FT81X Embedded Video Engine Datasheet
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3.5 Pin Description
Pin Number
Pin Name
Type
Description
FT810
FT811
FT812
FT813
-
-
1
1
R1
O
Bit 1 of Red RGB signals
Powered from pin VCCIO2
-
-
2
2
R0
O
Bit 0 of Red RGB signals
Powered from pin VCCIO2
1
1
3
3
AUDIO_L
O
Audio PWM out
Powered from pin VCC
2
2
4
4
GND
P
Ground
3
3
5
5
SCK
I
SPI clock input
Powered from pin VCCIO1
4
4
6
6
MISO/IO1
I/O
SPI Single mode: SPI MISO output
SPI Dual/Quad mode: SPI data line 1
Powered from pin VCCIO1
5
5
7
7
MOSI/IO0
I/O
SPI Single mode: SPI MOSI input
SPI Dual/Quad mode: SPI data line 0
Powered from pin VCCIO1
6
6
8
8
CS_N
I
SPI slave select input
Powered from pin VCCIO1
7
7
9
9
GPIO0/IO2
I/O
SPI Single/Dual mode: General purpose IO 0
SPI Quad mode: SPI data line 2
Powered from pin VCCIO1
8
8
10
10
GPIO1/IO3
I/O
SPI Single/Dual mode: General purpose IO 1
SPI Quad mode: SPI data line 3
Powered from pin VCCIO1
9
9
11
11
VCCIO1
P
I/O power supply for host interface pins. Support
1.8V, 2.5V or 3.3V.
10
10
12
12
GPIO2
I/O
General purpose IO 2
Powered from pin VCCIO1
11
11
13
13
INT_N
OD/O
Interrupt to host, open drain output(default) or push-
pull output, active low
12
12
14
14
PD_N
I
Chip power down mode control input, active low.
Connect to MCU GPIO for power management or
hardware reset function, or pulled up to VCCIO1
through 47kΩ resistor and 100nF to ground.
Powered from pin VCCIO1
-
-
15
15
GPIO3
I/O
General purpose IO 3
Powered from pin VCCIO1
13
13
16
16
X1/CLK
I
Crystal oscillator or clock input; Connect to GND if
not used.
3.3V peak input allowed.
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FT81X Embedded Video Engine Datasheet
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Pin Number
Pin Name
Type
Description
FT810
FT811
FT812
FT813
Powered from pin VCC.
14
14
17
17
X2
O
Crystal oscillator output; leave open if not used.
Powered from pin VCC.
15
15
18
18
GND
P
Ground
16
16
19
19
VCC
P
3.3V power supply input.
17
17
20
20
VOUT1V2
O
1.2V regulator output pin. Connect a 4.7uF
decoupling capacitor to GND.
18
18
21
21
VCC
P
3.3V power supply input.
22
22
VCCIO2
P
I/O power supply for RGB and touch pins.
For QFN-48 package, VCCIO2 is bonded together with
VCC pin;
For QFN-56 package, VCCIO2 is separate from VCC
pin. VCCIO2 supports 1.8V, 2.5V or 3.3V. VCCIO2
can be connected to different voltage with VCCIO1.
19
23
XP
AI/O
Connect to X right electrode of 4-wire resistive touch-
screen panel.
Powered from pin VCCIO2.
20
24
YP
AI/O
Connect to Y top electrode of 4-wire resistive touch-
screen panel.
Powered from pin VCCIO2.
21
25
XM
AI/O
Connect to X left electrode of 4-wire resistive touch-
screen panel.
Powered from pin VCCIO2.
22
26
YM
AI/O
Connect to Y bottom electrode of 4-wire resistive
touch-screen panel.
Powered from pin VCCIO2.
-
19
-
23
CTP_RST_N
O
Connect to reset pin of the CTPM.
Powered from pin VCCIO2.
-
20
-
24
CTP_INT_N
I
Connect to interrupt pin of the CTPM.
Powered from pin VCCIO2.
-
21
-
25
CTP_SCL
I/OD
Connect to I2C SCL pin of the CTPM.
Powered from pin VCCIO2.
-
22
-
26
CTP_SDA
I/OD
Connect to I2C SDA pin of the CTPM.
Powered from pin VCCIO2.
23
23
27
27
GND
P
Ground
24
24
28
28
BACKLIGHT
O
LED Backlight brightness PWM control signal.
Powered from pin VCCIO2.
25
25
29
29
DE
O
LCD Data Enable.
Powered from pin VCCIO2.
26
26
30
30
VSYNC
O
LCD Vertical Sync.
Powered from pin VCCIO2.
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FT81X Embedded Video Engine Datasheet
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Pin Number
Pin Name
Type
Description
FT810
FT811
FT812
FT813
27
27
31
31
HSYNC
O
LCD Horizontal Sync.
Powered from pin VCCIO2.
28
28
32
32
DISP
O
LCD Display Enable.
Powered from pin VCCIO2.
29
29
33
33
PCLK
O
LCD Pixel Clock.
Powered from pin VCCIO2.
30
30
34
34
B7
O
Bit 7 of Blue RGB signals.
Powered from pin VCCIO2.
31
31
35
35
B6
O
Bit 6 of Blue RGB signals.
Powered from pin VCCIO2.
32
32
36
36
B5
O
Bit 5 of Blue RGB signals.
Powered from pin VCCIO2.
33
33
37
37
B4
O
Bit 4 of Blue RGB signals.
Powered from pin VCCIO2.
34
34
38
38
B3
O
Bit 3 of Blue RGB signals.
Powered from pin VCCIO2.
35
35
39
39
B2
O
Bit 2 of Blue RGB signals.
Powered from pin VCCIO2.
-
-
40
40
B1
O
Bit 1 of Blue RGB signals.
Powered from pin VCCIO2.
-
-
41
41
B0
O
Bit 0 of Blue RGB signals.
Powered from pin VCCIO2.
36
36
42
42
GND
P
Ground
37
37
43
43
G7
O
Bit 7 of Green RGB signals.
Powered from pin VCCIO2.
38
38
44
44
G6
O
Bit 6 of Green RGB signals.
Powered from pin VCCIO2.
39
39
45
45
G5
O
Bit 5 of Green RGB signals.
Powered from pin VCCIO2.
40
40
46
46
G4
O
Bit 4 of Green RGB signals.
Powered from pin VCCIO2.
41
41
47
47
G3
O
Bit 3 of Green RGB signals.
Powered from pin VCCIO2.
42
42
48
48
G2
O
Bit 2 of Green RGB signals.
Powered from pin VCCIO2.
-
-
49
49
G1
O
Bit 1 of Green RGB signals.
Powered from pin VCCIO2.
-
-
50
50
G0
O
Bit 0 of Green RGB signals.
Powered from pin VCCIO2.
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FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Pin Number
Pin Name
Type
Description
FT810
FT811
FT812
FT813
43
43
51
51
R7
O
Bit 7 of Red RGB signals.
Powered from pin VCCIO2.
44
44
52
52
R6
O
Bit 6 of Red RGB signals.
Powered from pin VCCIO2.
45
45
53
53
R5
O
Bit 5 of Red RGB signals.
Powered from pin VCCIO2.
46
46
54
54
R4
O
Bit 4 of Red RGB signals.
Powered from pin VCCIO2.
47
47
55
55
R3
O
Bit 3 of Red RGB signals.
Powered from pin VCCIO2.
48
48
56
56
R2
O
Bit 2 of Red RGB signals.
Powered from pin VCCIO2.
EP
EP
EP
EP
GND
P
Ground. Exposed thermal pad.
Table 3-1 FT81x pin description
Note:
P : Power or ground
I : Input
O : Output
OD : Open drain output
I/O : Bi-direction Input and Output
AI/O: Analog Input and Output
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FT81X Embedded Video Engine Datasheet
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4 Function Description
The FT81x is a single chip, embedded video controller with the following function blocks:
Quad SPI Host Interface
System Clock
Graphics Engine
Parallel RGB video interface
Audio Engine
Touch-screen support and interface
Power Management
The functions for each block are briefly described in the following subsections.
4.1 Quad SPI Host Interface
The FT81x uses a quad serial parallel interface (QSPI) to communicate with host microcontrollers and
microprocessors.
4.1.1 QSPI Interface
The QSPI slave interface operates up to 30MHz. Only SPI mode 0 is supported. Refer to section 6.4.2 for
detailed timing specification. The QSPI can be configured as a SPI slave in SINGLE, DUAL or QUAD
channel modes.
By default the SPI slave operates in the SINGLE channel mode with MOSI as input from the master and
MISO as output to the master. DUAL and QUAD channel modes can be configured through the SPI slave
itself. To change the channel modes, write to register REG_SPI_WIDTH. The table below depicts the
setting.
REG_SPI_WIDTH[1:0]
Channel Mode
Data pins
Max bus speed
00
SINGLE – default mode
MISO, MOSI
30 MHz
01
DUAL
IO0, IO1
30 MHz
10
QUAD
IO0, IO1, IO2, IO3
25 MHz
11
Reserved
-
-
Table 4-1 QSPI channel selection
With DUAL/QUAD channel modes, the SPI data ports are now unidirectional. In these modes, each SPI
transaction (signified by CS_N going active low) will begin with the data ports set as inputs.
Hence, for writing to the FT81x, the protocol will operate as in FT800, with “WR-Command/Addr2, Addr1,
Addr0, DataX, DataY, DataZ …” The write operation is considered complete when CS_N goes inactive
high.
For reading from the FT81x, the protocol will still operate as in FT800, with “RD-Command/Addr2, Addr1,
Addr0, Dummy-Byte, DataX, DataY, DataZ”. However as the data ports are now unidirectional, a change
of port direction will occur before DataX is clocked out of the FT81x. Therefore it is important that the
firmware controlling the SPI master changes the SPI master data port direction to “input” after
transmitting Addr0. The FT81x will not change the port direction till it starts to clock out DataX. Hence,
the Dummy-Byte cycles will be used as a change-over period when neither the SPI master nor slave will
be driving the bus; the data paths thus must have pull-ups/pull-downs. The SPI slave from the FT81x will
reset all its data ports’ direction to input once CS_N goes inactive high (i.e. at the end of the current SPI
master transaction).
The diagram depicts the behaviour of both the SPI master and slave in the master read case.
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FT81X Embedded Video Engine Datasheet
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Figure 4-1 SPI master and slave in the master read case
In the DUAL channel mode, MISO (MSB) and MOSI are used while in the QUAD channel mode. IO3
(MSB), IO2, MISO and MOSI are used.
Figure 4-2 illustrates a direct connection to a 1.8-3.3V IO MPU/MCU with single or dual SPI interface.
Figure 4-3 illustrates a direct connection to a 1.8-3.3V IO MPU/MCU with Quad SPI interface.
Figure 4-2 Single/Dual SPI Interface connection
SPI Master drives
the data bus
SS
WR /
Addr2
Addr
1
Addr
2
Dum
my
Data
X
Data
Y
Data
0
SPI Slave drives the
data bus
Bus not
driven
SPI Master changes
data ports into inputs
SPI Slave changes
data ports into outputs
SPI Slave resets data
ports into inputs
GND
GND
SS#
MISO
MOSI
SCLK
PD#
INT#
CS_N
MISO/IO1
MOSI/IO0
SCK
PD_N
INT_N
FT81x
1.8-3.3V
VCCIO1
3.3V
VCC
4.7k
MPU/MCU
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FT81X Embedded Video Engine Datasheet
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Figure 4-3 Quad SPI Interface connection
4.1.2 Serial Data Protocol
The FT81x appears to the host MPU/MCU as a memory-mapped SPI device. The host communicates with
the FT81x using reads and writes to a large (4 megabyte) address space. Within this address space are
dedicated areas for graphics, audio and touch control. Refer to section 5 for the detailed memory map.
The host reads and writes the FT81x address space using SPI transactions. These transactions are
memory read, memory write and command write. Serial data is sent by the most significant bit first.
Each transaction starts with CS_N goes low, and ends when CS_N goes high. There’s no limit on data
length within one transaction, as long as the memory address is continuous.
4.1.3 Host Memory Read
For SPI memory read transactions, the host sends two zero bits, followed by the 22-bit address. This is
followed by a dummy byte. After the dummy byte, the FT81x responds to each host byte with read data
bytes.
Byte n
Table 4-2 Host memory read transaction
7
6
5
4
3
2
1
0
0
0
Address [21:16]
Address [15:8]
Address [7:0]
Dummy byte
Byte 0
GND
GND
SCLK
MISO
IO2
SS#
PD#
INT#
SCK
IO1
IO2
CS_N
PD_N
INT_N
FT81x
1.8-3.3V
VCCIO1
3.3V
VCC
4.7k
MPU/MCU
MOSI
IO3
IO0
IO3
Read Data
Write
Address
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FT81X Embedded Video Engine Datasheet
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4.1.4 Host Memory Write
For SPI memory write transactions, the host sends a ‘1’ bit and ‘0’ bit, followed by the 22-bit address.
This is followed by the write data.
Byte n
Table 4-3 Host memory write transaction
4.1.5 Host Command
When sending a command, the host transmits a 3 byte command. Error! Reference source not found.
Lists all the host command functions.
For SPI command transactions, the host sends a ‘0’ bit and ‘1’ bit, followed by the 6-bit command code.
The 2nd byte can be either 00h, or the parameter of that command. The 3rd byte is fixed at 00h.
All SPI commands except the system reset can only be executed when the SPI is in the Single channel
mode. They will be ignored when the SPI is in either Dual or Quad channel mode.
Some commands are used to configure the device and these configurations will be reset upon receiving
the SPI PWRDOWN command, except those that configure the pin state during power down. These
commands will be sticky unless reconfigured or power-on-reset (POR) occurs.
1st Byte
2nd Byte
3rd Byte
Table 4-4 Host command transaction
1st Byte
2nd byte
3rd byte
Command
Description
Power Modes
00000000b
00000000b
00000000b
00h
ACTIVE
Switch from Standby/Sleep/PWRDOWN
modes to active mode. Dummy memory
read from address 0(read twice) generates
ACTIVE command.
7
6
5
4
3
2
1
0
1
0
Address [21:16]
Address [15:8]
Address [7:0]
Byte 0
7
6
5
4
3
2
1
0
0
1
Command [5:0]
Parameter for the command
0
0
0
0
0
0
0
0
Write Data
Write
Address
Copyright © Bridgetek Pte Ltd 17
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
1st Byte
2nd byte
3rd byte
Command
Description
01000001b
00000000b
00000000b
41h
STANDBY
Put FT81x core to standby mode. Clock gate
off, PLL and Oscillator remain on (default).
ACTIVE command to wake up.
01000010b
00000000b
00000000b
42h
SLEEP
Put FT81x core to sleep mode. Clock gate
off, PLL and Oscillator off. ACTIVE command
to wake up.
01000011b
01010000b
00000000b
00000000b
43h/50h
PWRDOWN
Switch off 1.2V core voltage to the digital
core circuits. Clock, PLL and Oscillator off.
SPI is alive. ACTIVE command to wake up.
01000100b
xx
00000000b
49h
PD_ROMS
Select power down individual ROMs; Byte2
determines which ROM to power down or
up. A 1 on a bit powers down the
corresponding block; a 0 on a bit powers up
the corresponding block. As these are not
readable, the host must remember the
setting on its own.
Byte2[7]
ROM_MAIN
Byte2[6]
ROM_RCOSATAN
Byte2[5]
ROM_SAMPLE
Byte2[4]
ROM_JABOOT
Byte2[3]
ROM_J1BOOT
Byte2[2-
0]
reserved
Clock and Reset
01000100b
00000000b
00000000b
44h
CLKEXT
Select PLL input from external crystal
oscillator or external input clock. No effect if
external clock is already selected, otherwise
a system reset will be generated
01001000b
00000000b
00000000b
48h
CLKINT
Select PLL input from internal relaxation
oscillator (default). No effect if internal clock
is already selected, otherwise a system
reset will be generated
01100001b
01100010b
xx
00000000b
61h/62h
CLKSEL
This command will only be effective when
the PLL is stopped (SLEEP mode).
For compatibility to FT800/FT801, set Byte2
to 0x00. This will set the PLL clock back to
default (60 MHz).
Byte2
[5:0]
sets the clock frequency
0
Set to default clock speed
1
Reserved
2 to 5
2 to 5 times the osc
frequency (i.e. 24 to 60MHz
with 12MHz oscillator)
Copyright © Bridgetek Pte Ltd 18
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
1st Byte
2nd byte
3rd byte
Command
Description
Byte2
[7:6]
sets the PLL range
0
When Byte2[5:0] = 0, 2, 3
1
When Byte2[5:0] = 4, 5
01101000b
00000000b
00000000b
68h
RST_PULSE
Send reset pulse to FT81x core. The
behaviour is the same as POR except that
settings done through SPI commands will
not be affected
Configuration
01110000b
xx
00000000b
70h
PINDRIVE
This will set the drive strength for various
pins. For FT800/FT801 compatibility, by
default those settings are from the GPIO
registers. FT81x supports setting the drive
strength via SPI command instead.
When PINDRIVE for a pin from the SPI
command is not updated, the drive strength
will be determined by its corresponding
GPIO register bits, if they exist. If they don’t
exist, a hard coded setting is used. Please
refer to Error! Reference source not
found. for default values.
When PINDRIVE for a pin from the SPI
command is updated, it will override the
corresponding setting in the GPIO register
bits.
Byte2 determines which pin and the setting
are to be updated.
Byte2[1:0] determine the drive strength:
Byte2
[1:0]
Drive Strength
0h
5mA
1h
10.0mA
2h
15.0mA
3h
20.0mA
Byte[7:2] determine which pin/pin group to
set:
Byte2
[7:2]
Pin / Pin Group
00h
GPIO 0
01h
GPIO 1
Copyright © Bridgetek Pte Ltd 19
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
1st Byte
2nd byte
3rd byte
Command
Description
02h
GPIO 2
03h
GPIO 3
04-07h
Reserved
08h
DISP
09h
DE
0Ah
VSYNC / HSYNC
0Bh
PCLK
0Ch
BACKLIGHT
0Dh
R[7:0], G[7:0], B[7:0]
0Eh
AUDIO_L
0Fh
INT_N
10h
CTP_RST_N
11h
CTP_SCL
12h
CTP_SDA
13h
SPI MISO/MOSI/IO2/IO3
Others
Reserved
Note: GPIO0 shares the same pin as SPI
IO2 and GPIO1 with SPI IO3. When SPI is
set in Quad mode, IO2 and IO3 will inherit
the drive strength set in GROUP 13h;
otherwise GPIO0 and GPIO1 will inherit the
drive strength from GROUP 00h and 01h
respectively.
01110001b
xx
00000000b
71h
PIN_PD_STA
TE
During power down, all output and in/out
pins will not be driven. Please refer to
Error! Reference source not found. for
their default power down state.
These settings will only be effective during
power down and will not affect normal
operations. Also note that these
configuration bits are sticky and, unlike
other configuration bits, will not reset to
default values upon exiting power down.
Only POR will reset them.
Byte2 determines which pin and the setting
are to be updated.
Byte2[1:0] determine the pin state.
Copyright © Bridgetek Pte Ltd 20
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
1st Byte
2nd byte
3rd byte
Command
Description
Byte2 [1:0]
Pin Setting
0h
Float
1h
Pull-Down
2h
Pull-Up
3h
Reserved
Byte2[7:2] determine which pin/pin group
to set.
Please refer to the table in command
PINDRIVE entry.
Table 4-5 Host command list
NOTE: Any command code not specified is reserved and should not be used by the software
4.1.6 Interrupts
The interrupt output pin is enabled by REG_INT_EN. When REG_INT_EN is 0, INT_N is tri-state (pulled to
high by external pull-up resistor). When REG_INT_EN is 1, INT_N is driven low when any of the interrupt
flags in REG_INT_FLAGS are high, after masking with REG_INT_MASK. Writing a ‘1’ in any bit of
REG_INT_MASK will enable the corresponding interrupt. Each bit in REG_INT_FLAGS is set by a
corresponding interrupt source. REG_INT_FLAGS is readable by the host at any time, and clears when
read.
The INT_N pin is open-drain (OD) output by default. It can be configured to push-pull output by register
REG_GPIOX.
Bit
7
6
5
4
Interrupt Sources
CONVCOMPLETE
CMDFLAG
CMDEMPTY
PLAYBACK
Conditions
Touch-screen
conversions
completed
Command FIFO
flag
Command FIFO
empty
Audio playback
ended
Bit
3
2
1
0
Interrupt Sources
SOUND
TAG
TOUCH
SWAP
Conditions
Sound effect
ended
Touch-screen tag
value change
touch detected
Display list swap
occurred
Table 4-6 Interrupt Flags bit assignment
4.2 System Clock
Copyright © Bridgetek Pte Ltd 21
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
4.2.1 Clock Source
The FT81x can be configured to use any of the three clock sources for system clock:
Internal relaxation oscillator clock (default)
External 12MHz crystal
External 12MHz square wave clock
Figure 4-4, Figure 4-5 and Figure 4-6 show the pin connections for these clock options.
Figure 4-4 Internal relaxation oscillator connection
Figure 4-5 Crystal oscillator connection
Figure 4-6 External clock input
4.2.2 Phase Locked Loop
The internal PLL takes an input clock from the oscillator, and generates clocks to all internal circuits,
including the graphics engine, audio engine and touch engine.
Copyright © Bridgetek Pte Ltd 22
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
4.2.3 Clock Enable
At power-on the FT81x enters sleep mode. The internal relaxation oscillator is selected for the PLL clock
source. The system clock will be enabled when the following step is executed:
Host sends an “ACTIVE” command
If the application chooses to use the external clock source (12MHz crystal or clock), the following steps
shall be executed:
Host sends a “CLKEXT” command
Host sends an “ACTIVE” command
4.2.4 Clock Frequency
By default the system clock is 60MHz when the input clock is 12MHz. The host is allowed to switch the
system clock to other frequencies (48MHz, 36MHz, and 24MHz) by the host command “CLKSEL”. The
clock switching command shall be sent in SLEEP mode only.
When using the internal relaxation oscillator, its clock frequency is trimmed to be 12MHz at factory.
Software is allowed to change the frequency to a lower value by programming the register REG_TRIM.
Note that software shall not change the internal oscillator frequency to be higher than 12MHz.
4.3 Graphics Engine
4.3.1 Introduction
The graphics engine executes the display list once for every horizontal line. It executes the primitive
objects in the display list and constructs the display line buffer. The horizontal pixel content in the line
buffer is updated if the object is visible at the horizontal line.
Main features of the graphics engine are:
The primitive objects supported by the graphics processor are: lines, points, rectangles, bitmaps
(comprehensive set of formats), text display, plotting bar graph, edge strips, and line strips, etc.
Operations such as stencil test, alpha blending and masking are useful for creating a rich set of
effects such as shadows, transitions, reveals, fades and wipes.
Anti-aliasing of the primitive objects (except bitmaps) gives a smoothing effect to the viewer.
Bitmap transformations enable operations such as translate, scale and rotate.
Display pixels are plotted with 1/16th pixel precision.
Four levels of graphics states
Tag buffer detection
The graphics engine also supports customized built-in widgets and functionalities such as jpeg decode,
screen saver, calibration etc. The graphics engine interprets commands from the MPU host via a 4 Kbyte
FIFO in the FT81x memory at RAM_CMD. The MPU/MCU writes commands into the FIFO, and the graphics
engine reads and executes the commands. The MPU/MCU updates the register REG_CMD_WRITE to
indicate that there are new commands in the FIFO, and the graphics engine updates REG_CMD_READ
after commands have been executed.
Main features supported are:
Drawing of widgets such as buttons, clock, keys, gauges, text displays, progress bars, sliders,
toggle switches, dials, gradients, etc.
JPEG and motion-JPEG decode
Inflate functionality (zlib inflate is supported)
Timed interrupt (generate an interrupt to the host processor after a specified number of
milliseconds)
In-built animated functionalities such as displaying logo, calibration, spinner, screen saver and
sketch
Snapshot feature to capture the current graphics display
Copyright © Bridgetek Pte Ltd 23
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
For a complete list of graphics engine display commands and widgets refer to
FT81x_Series_Programmer_Guide, Chapter 4.
4.3.2 ROM and RAM Fonts
The FT81x has built in ROM character bitmaps as font metrics. The graphics engine can use these metrics
when drawing text fonts. There are a total of 19 ROM fonts, numbered with font handle 16-34. The user
can define and load customized font metrics into RAM_G, which can be used by display command with
handle 0-15.
Each font metric block has a 148 byte font table which defines the parameters of the font and the pointer
of font image. The font table format is shown in Error! Reference source not found..
Address Offset
Size(byte)
Parameter Description
0
128
width of each font character, in pixels
128
4
font bitmap format, for example L1, L4 or L8
132
4
font line stride, in bytes
136
4
font width, in pixels
140
4
font height, in pixels
144
4
pointer to font image data in memory
Table 4-7 Font table format
The ROM fonts are stored in the memory space ROM_FONT. The ROM font table is also stored in the
ROM. The starting address of the ROM font table for font index 16 is stored at ROM_FONT_ADDR, with
other font tables following. The ROM font table and individual character width (in pixel) are listed in
Error! Reference source not found. through Error! Reference source not found.. Font index 16, 18
and 20-31 are for basic ASCII characters (code 0-127), while font index 17 and 19 are for Extended
ASCII characters (code 128-255). The character width for font index 16 through 19 is fixed at 8 pixels for
any of the ASCII characters.
Font Index
1
6
1
7
1
8
1
9
2
0
2
1
2
2
2
3
2
4
2
5
2
6
2
7
2
8
2
9
3
0
3
1
3
2
3
3
3
4
Font format
L
1
L
1
L
1
L
1
L
1
L
1
L
1
L
1
L
1
L
1
L
4
L
4
L
4
L
4
L
4
L
4
L
4
L
4
L
4
Line stride
1
1
1
1
2
2
2
3
3
4
7
8
9
1
1
1
4
1
8
2
3
3
0
3
9
Font width
(max)
8
8
8
8
1
1
1
3
1
7
1
8
2
5
3
4
1
3
1
5
1
9
2
1
2
8
3
7
4
9
6
3
8
2
Font height
8
8
1
6
1
6
1
3
1
7
2
0
2
2
2
9
3
8
1
6
2
0
2
5
2
8
3
6
4
9
6
3
8
3
1
0
8
Image
pointer start
address
(hex)
2FF7FC
2FFBFC
2FE7FC
2FEFFC
2FDAFC
2FCD3C
2FBD7C
2FA17C
2F7E3C
2F3D1C
2F181C
2ED61C
2E799C
2DFBBC
2D263C
2BAC3C
2945FC
251E1C
1E1B5C
Table 4-8 ROM font table
Font Index
=>
16/
18
2
0
2
1
2
2
2
3
2
4
2
5
2
6
2
7
2
8
2
9
3
0
3
1
3
2
3
3
3
4
ASCII Character width
in pixels
0
NULL
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
SOH
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2
STX
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
3
ETX
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4
EOT
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
5
ENQ
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6
ACK
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
7
BEL
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
8
BS
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Copyright © Bridgetek Pte Ltd 24
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Font Index
=>
16/
18
2
0
2
1
2
2
2
3
2
4
2
5
2
6
2
7
2
8
2
9
3
0
3
1
3
2
3
3
3
4
9
HT
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
10
LF
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
11
VT
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
12
FF
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
13
CR
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
14
SO
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
15
SI
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
16
DLE
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
17
DC1
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
18
DC2
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
19
DC3
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
20
DC4
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
21
NAK
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
22
SYN
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
23
ETB
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
24
CAN
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
25
EM
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
26
SUB
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
27
ESC
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
28
FS
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
29
GS
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
30
RS
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
31
US
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
32
spac
e
8
3
4
5
5
6
9
3
4
5
6
8
10
13
18
23
33
!
8
3
4
5
6
6
9
3
4
6
6
9
11
15
19
25
34
"
8
4
5
6
5
8
12
5
6
7
8
12
15
19
25
33
35
#
8
6
8
9
10
14
19
10
11
14
15
19
26
33
44
57
36
$
8
6
8
9
10
13
18
8
10
11
15
18
25
31
41
54
37
%
8
9
12
14
16
22
29
11
13
16
17
23
31
40
52
68
38
&
8
8
10
11
13
17
22
9
11
14
15
19
26
34
44
57
39
'
8
2
3
3
3
6
6
3
4
4
5
7
10
11
15
20
40
(
8
4
5
6
6
8
11
5
6
7
9
11
15
18
24
31
41
)
8
4
5
6
6
8
11
5
6
8
8
10
14
18
24
31
42
*
8
4
7
6
7
10
13
7
8
10
11
14
18
24
31
40
43
+
8
6
9
10
10
14
19
9
10
12
14
17
24
30
41
52
44
,
8
3
3
4
5
6
9
3
4
4
5
7
9
12
16
20
45
-
8
4
4
5
6
8
11
6
7
10
11
15
18
24
32
41
46
.
8
3
3
4
5
6
9
3
4
6
7
8
11
14
19
24
47
/
8
3
4
5
5
7
9
6
7
9
10
13
17
22
29
38
48
0
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
49
1
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
50
2
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
51
3
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
52
4
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
53
5
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
54
6
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
55
7
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
56
8
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
57
9
8
6
8
9
10
13
18
8
10
12
14
17
24
30
40
52
58
:
8
3
3
4
5
6
9
3
4
6
6
7
10
13
18
23
59
;
8
3
4
4
5
6
9
3
4
6
6
8
10
14
18
23
60
<
8
6
8
10
10
15
19
8
9
11
12
16
21
28
36
46
61
=
8
5
9
10
11
15
19
8
9
13
14
18
23
30
40
52
Copyright © Bridgetek Pte Ltd 25
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Font Index
=>
16/
18
2
0
2
1
2
2
2
3
2
4
2
5
2
6
2
7
2
8
2
9
3
0
3
1
3
2
3
3
3
4
62
>
8
6
8
10
10
15
19
8
9
11
13
16
22
29
37
48
63
?
8
6
8
9
10
12
18
7
9
10
12
15
20
26
34
44
64
@
8
11
13
17
18
25
34
13
15
19
21
28
37
49
63
82
65
A
8
7
9
11
13
17
22
9
11
13
15
20
27
34
45
58
66
B
8
7
9
11
13
17
22
9
10
14
15
19
27
34
45
58
67
C
8
8
10
12
14
18
24
9
11
13
15
20
26
34
45
58
68
D
8
8
10
12
14
18
24
9
11
14
17
22
28
36
48
63
69
E
8
7
9
11
13
16
22
7
9
12
13
16
23
29
39
50
70
F
8
6
8
10
12
14
20
7
9
12
13
17
22
29
39
50
71
G
8
8
11
13
15
19
25
9
11
14
16
22
28
37
48
62
72
H
8
8
10
12
14
18
24
9
11
15
17
23
29
37
50
65
73
I
8
3
4
4
6
8
9
4
5
6
7
9
12
15
20
26
74
J
8
5
7
8
10
13
16
8
9
12
13
17
23
30
40
50
75
K
8
7
9
11
13
18
22
9
11
14
16
19
26
34
45
58
76
L
8
6
8
9
11
14
18
7
9
12
13
17
22
29
39
51
77
M
8
9
12
13
16
21
27
11
14
19
21
26
35
46
62
79
78
N
8
8
10
12
14
18
24
9
11
15
17
23
29
37
50
65
79
O
8
8
11
13
15
18
25
10
12
14
16
22
28
37
49
63
80
P
8
7
9
11
13
16
22
9
10
14
15
19
26
34
45
58
81
Q
8
8
11
13
15
18
26
10
12
14
17
22
29
38
50
64
82
R
8
7
10
12
14
17
24
9
11
13
15
19
27
33
45
58
83
S
8
7
9
11
13
16
22
9
11
12
14
20
26
33
43
56
84
T
8
5
9
10
12
16
20
10
12
14
15
19
26
32
42
56
85
U
8
8
10
12
14
18
24
9
11
13
17
21
28
37
48
62
86
V
8
7
9
11
13
17
22
9
11
14
15
20
27
34
45
58
87
W
8
9
13
15
18
22
31
12
15
18
21
27
36
46
61
79
88
X
8
7
9
11
13
17
22
9
11
13
15
20
27
34
45
58
89
Y
8
7
9
11
13
16
22
9
10
14
15
19
26
34
45
58
90
Z
8
7
9
10
12
15
20
9
11
13
14
18
25
32
42
55
91
[
8
3
4
5
5
7
9
4
5
6
7
9
12
15
19
25
92
\
8
3
4
5
5
7
9
6
7
9
10
13
18
22
29
38
93
]
8
3
4
5
5
7
9
4
5
7
7
9
12
15
19
25
94
^
8
6
7
8
9
12
16
6
7
9
10
13
18
23
30
38
95
_
8
6
8
9
11
14
18
8
10
11
13
16
21
26
34
43
96
`
8
3
5
6
4
7
11
4
5
7
8
10
13
17
22
29
97
a
8
5
8
9
11
13
18
8
9
11
13
17
23
30
39
50
98
b
8
6
7
9
11
14
18
8
9
11
14
17
24
31
40
52
99
c
8
5
7
8
10
12
16
8
9
11
12
16
22
28
37
48
100
d
8
6
8
9
11
14
18
8
10
12
14
17
24
31
40
52
101
e
8
5
8
9
10
13
18
8
9
11
12
16
22
29
37
48
102
f
8
4
4
5
6
8
9
6
7
8
10
12
15
19
25
31
103
g
8
6
8
9
11
14
18
8
10
11
14
18
24
31
41
52
104
h
8
6
8
9
10
13
18
8
9
11
14
17
24
31
41
52
105
i
8
2
3
3
4
6
7
3
4
6
6
7
10
13
18
23
106
j
8
2
3
4
4
6
7
3
4
6
6
8
11
14
18
23
107
k
8
5
7
8
9
12
16
7
9
11
13
16
22
28
36
47
108
l
8
2
3
3
4
6
7
3
4
6
6
7
10
13
18
23
109
m
8
8
11
14
16
20
27
11
15
18
21
27
36
47
63
80
110
n
8
6
8
9
10
14
18
8
9
11
14
17
24
31
41
52
111
o
8
6
8
9
11
13
18
8
10
12
13
17
24
31
40
52
112
p
8
6
8
9
11
14
18
8
9
11
14
17
24
31
40
51
113
q
8
6
8
9
11
14
18
8
10
12
13
17
24
31
40
52
114
r
8
4
5
5
6
9
11
5
6
7
9
11
15
19
25
32
115
s
8
5
7
8
9
12
16
7
9
11
12
17
22
29
38
48
Copyright © Bridgetek Pte Ltd 26
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Font Index
=>
16/
18
2
0
2
1
2
2
2
3
2
4
2
5
2
6
2
7
2
8
2
9
3
0
3
1
3
2
3
3
3
4
116
t
8
4
4
5
6
8
9
6
7
8
9
11
14
17
23
29
117
u
8
5
7
9
10
14
18
8
9
12
14
17
24
31
41
52
118
v
8
6
7
8
10
13
16
7
9
11
12
16
21
27
36
46
119
w
8
8
10
12
14
18
23
11
13
16
18
23
32
41
54
70
120
x
8
6
7
8
10
12
16
7
9
11
12
16
21
27
36
46
121
y
8
5
7
8
10
13
16
7
9
11
12
16
21
27
36
46
122
z
8
5
7
8
9
12
16
8
9
11
12
15
22
27
36
46
123
{
8
3
5
6
6
8
11
5
6
8
8
11
15
18
24
31
124
|
8
3
3
4
5
6
9
3
4
5
6
7
10
14
18
23
125
}
8
3
5
6
6
8
11
5
6
7
9
10
15
18
24
31
126
~
8
7
8
10
10
14
19
10
11
14
15
21
29
36
47
63
127
DEL
8
0
0
0
0
0
0
3
4
5
6
5
10
13
18
23
Table 4-9 ROM font ASCII character width in pixels
Decimal
Symbol
Decimal
Symbol
Decimal
Symbol
Decimal
Symbol
Decimal
Symbol
Decimal
Symbol
Decimal
Symbol
Decimal
Symbol
128
Ç
144
É
160
á
176
░
192
└
208
╨
224
α
240
Ξ
129
ü
145
æ
161
í
177
▒
193
┴
209
╤
225
ß
241
±
130
é
146
Æ
162
ó
178
▓
194
┬
210
╥
226
Γ
242
≥
131
â
147
ô
163
ú
179
│
195
├
211
╙
227
∏
243
≤
132
ä
148
ö
164
ñ
180
┤
196
─
212
╘
228
Σ
244
⌠
133
à
149
ò
165
Ñ
181
╡
197
┼
213
╒
229
σ
245
⌡
134
å
150
û
166
ª
182
╢
198
╞
214
╓
230
µ
246
÷
135
ç
151
ù
167
º
183
╖
199
╟
215
╫
231
τ
247
≈
136
ê
152
ÿ
168
¿
184
╕
200
╚
216
╪
232
Φ
248
°
137
ë
153
Ö
169
⌐
185
╣
201
╔
217
┘
233
θ
249
•
138
è
154
Ü
170
¬
186
║
202
╩
218
┌
234
Ω
250
·
139
ï
155
₵
171
½
187
╗
203
╦
219
█
235
δ
251
√
140
î
156
£
172
¼
188
╝
204
╠
220
▄
236
ω
252
ⁿ
141
ì
157
¥
173
¡
189
╜
205
═
221
▌
237
φ
253
²
142
Ä
158
Pt
174
«
190
╛
206
╬
222
▐
238
Ɛ
254
■
143
Å
159
ƒ
175
»
191
┐
207
╧
223
▀
239
Π
255
nbsp
Table 4-10 ROM font Extended ASCII characters
Note: Font 17 and 19 are extended ASCII characters, with width fixed at 8 pixels for all characters.
Note: All fonts included in the FT81x ROM are widely available to the market-place for general usage. See
section nine for specific copyright data and links to the corresponding license agreements.
4.4 Parallel RGB Interface
The RGB parallel interface consists of 23 or 29 signals - DISP, PCLK, VSYNC, HSYNC, DE, 6 or 8 signals
each for R, G and B.
A set of RGB registers configure the LCD operation and timing parameters.
REG_PCLK is the PCLK divisor. The default value is 0, which means the PCLK output is disabled. When
REG_PCLK is none 0 (1-1023), the PCLK frequency can be calculated as:
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FT81X Embedded Video Engine Datasheet
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PCLK frequency = System Clock frequency / REG_PCLK
The FT81x system clock frequency is programmable. Some of the possible PCLK frequencies that FT81x
supports are listed inError! Reference source not found..
REG_PCLK
System Clock Frequency (MHz)
60(default)
48
36
24
1
60
48
36
24
2
30
24
18
12
3
20
16
12
8.0
4
15
12
9.0
6.0
5
12
9.6
7.2
4.8
6
10
8.0
6.0
4.0
7
8.6
6.9
5.1
3.4
8
7.5
6.0
4.5
3.0
9
6.7
5.3
4.0
2.7
10
6.0
4.8
3.6
2.4
Table 4-11 RGB PCLK frequency
REG_PCLK_POL defines the clock polarity, with 0 for positive active clock edge, and 1 for negative clock
edge.
REG_CSPREAD controls the transition of RGB signals with respect to the PCLK active clock edge. When
REG_CSPREAD=0, R[7:0], G[7:0] and B[7:0] signals change following the active edge of PCLK. When
REG_CSPREAD=1, R[7:0] changes a PCLK clock early and B[7:0] a PCLK clock later, which helps reduce
the switching noise.
REG_DITHER enables colour dither. This option improves the half-tone appearance on displays.
Internally, the graphics engine computes the colour values at an 8 bit precision; however, the LCD colour
at a lower precision is sufficient. The FT810/FT811 output is only 6 bits per colour in 6:6:6 formats and a
2X2 dither matrix allow the truncated bits to contribute to the final colour values.
REG_OUTBITS gives the bit width of each colour channel, the default is 6/6/6(for FT810/FT811) or
8/8/8(for FT812/FT813) bits for each R/G/B colour. A lower value means fewer bits are output for each
channel allowing dithering on lower precision LCD displays.
REG_SWIZZLE controls the arrangement of the output colour pins, to help the PCB route different LCD
panel arrangements. Bit 0 of the register causes the order of bits in each colour channel to be reversed.
Bits 1-3 control the RGB order. Setting Bit 1 causes R and B channels to be swapped. Setting Bit 3 allows
rotation to be enabled. If Bit 3 is set, then (R,G,B) is rotated right if bit 2 is one, or left if bit 2 is zero.
REG_SWIZZLE
PINS (FT810/FT811, 6 bits)
PINS (FT812/FT813, 8 bits)
b3
b2
b1
b0
R7, R6, R5,
R4, R3, R2
G7, G6, G5,
G4, G3, G2
B7, B6, B5,
B4, B3, B2
R7, R6,
R5, R4,
R3, R2,
R1, R0
G7, G6,
G5, G4,
G3, G2,
G1, G0
B7, B6,
B5, B4,
B3, B2,
B1, B0
0
X
0
0
R[7:2]
G[7:2]
B[7:2]
R[7:0]
G[7:0]
B[7:0]
0
X
0
1
R[2:7]
G[2:7]
B[2:7]
R[0:7]
G[0:7]
B[0:7]
0
X
1
0
B[7:2]
G[7:2]
R[7:2]
B[7:0]
G[7:0]
R[7:0]
0
X
1
1
B[2:7]
G[2:7]
R[2:7]
B[0:7]
G[0:7]
R[0:7]
Copyright © Bridgetek Pte Ltd 28
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
1
0
0
0
B[7:2]
R[7:2]
G[7:2]
B[7:0]
R[7:0]
G[7:0]
1
0
0
1
B[2:7]
R[2:7]
G[2:7]
B[0:7]
R[0:7]
G[0:7]
1
0
1
0
G[7:2]
R[7:2]
B[7:2]
G[7:0]
R[7:0]
B[7:0]
1
0
1
1
G[2:7]
R[2:7]
B[2:7]
G[0:7]
R[0:7]
B[0:7]
1
1
0
0
G[7:2]
B[7:2]
R[7:2]
G[7:0]
B[7:0]
R[7:0]
1
1
0
1
G[2:7]
B[2:7]
R[2:7]
G[0:7]
B[0:7]
R[0:7]
1
1
1
0
R[7:2]
B[7:2]
G[7:2]
R[7:0]
B[7:0]
G[7:0]
1
1
1
1
R[2:7]
B[2:7]
G[2:7]
R[0:7]
B[0:7]
G[0:7]
Table 4-12 REG_SWIZZLE RGB Pins Mapping
REG_HCYCLE, REG_HSIZE, REG_HOFFSET, REG_HSYNC0 and REG_HSYNC1 define the LCD horizontal
timings. Each register has 12 bits to allow programmable range of 0-4095 PCLK cycles. REG_VCYCLE,
REG_VSIZE, REG_VOFFSET, REG_VSYNC0 and REG_VSYNC1 define the LCD vertical timings. Each
register has 12 bits to allow programmable range of 0-4095 lines.
Register
Display
Parameter
Description
Horizontal
REG_HCYCLE
TH
Total length of line (visible and non-visible) (in PCLKs)
REG_HSIZE
THD
Length of visible part of line (in PCLKs)
REG_HOFFSET
THF + THP + THB
Length of non-visible part of line (in PCLK cycles)
REG_HSYNC0
THF
Horizontal Front Porch (in PCLK cycles)
REG_HSYNC1
THF + THP
Horizontal Front Porch plus Hsync Pulse width (in PCLK
cycles)
Vertical
REG_VCYCLE
TV
Total number of lines (visible and non-visible) (in lines)
REG_VSIZE
TVD
Number of visible lines (in lines)
REG_VOFFSET
TVF + TVP + TVB
Number of non-visible lines (in lines)
REG_VSYNC0
TVF
Vertical Front Porch (in lines)
REG_VSYNC1
TVF + TVP
Vertical Front Porch plus Vsync Pulse width (in lines)
Table 4-13 Registers for RGB horizontal and vertical timings
Copyright © Bridgetek Pte Ltd 29
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Figure 4-7 RGB timing waveforms
4.5 Miscellaneous Control
4.5.1 Backlight Control Pin
The backlight dimming control pin (BACKLIGHT) is a pulse width modulated (PWM) signal controlled by
two registers: REG_PWM_HZ and REG_PWM_DUTY. REG_PWM_HZ specifies the PWM output frequency,
the range is 250-10000 Hz. REG_PWM_DUTY specifies the duty cycle; the range is 0-128. A value of 0
means that the PWM is completely off and 128 means completely on.
The BACKLIGHT pin will output low when the DISP pin is not enabled (i.e. logic 0).
4.5.2 DISP Control Pin
The DISP pin is a general purpose output that can be used to enable, or reset the LCD display panel. The
pin is controlled by writing to Bit 7 of the REG_GPIO register, or bit 15 of REG_GPIOX.
4.5.3 General Purpose IO pins
Depending on the package, the FT81x can be configured to use up to 4 GPIO pins. These GPIO pins are
controlled by the REG_GPIOX_DIR and REG_GPIOX registers. Alternatively the GPIO0 and GPIO1 pins
can also be controlled by REG_GPIO_DIR and REG_GPIO to maintain backward compatibility with the
FT800/FT801.
When the QSPI is enabled in Quad mode, GPIO0/IO2 and GPIO1/IO3 pins are used as data lines of the
QSPI.
Copyright © Bridgetek Pte Ltd 30
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
4.5.4 Pins Drive Current Control
The output drive current of output pins can be changed as per the following table by writing to bit[6:2] of
REG_GPIO register or bit[14:10] of REG_GPIOX register. Alternatively, use the SPI command PINDRIVE
to change the individual pin drive strength.
REG_GPIO
Bit[6:5]
Bit[4]
Bit[3:2]
REG_GPIOX
Bit[14:13]
Bit[12]
Bit[11:10]
Value
00b
#
01b
10b
11b
0b#
1b
00b#
01b
10b
11b
Drive
Current
5m
A
10mA
15mA
20mA
5mA
10mA
5mA
10mA
15mA
20mA
Pins
GPIO0
GPIO1
GPIO2
GPIO3
CTP_RST_N
PCLK
DISP
VSYNC
HSYNC
DE
R7..R0
G7..G0
B7..B0
BACKLIGHT
MISO
MOSI
IO2
IO3
INT_N
Table 4-14 Output drive current selection
Note: #Default value
4.6 Audio Engine
FT81x provides mono audio output through a PWM output pin, AUDIO_L. It outputs two audio sources,
the sound synthesizer and audio file playback.
4.6.1 Sound Synthesizer
A sound processor, AUDIO ENGINE, generates the sound effects from a small ROM library of waves table.
To play a sound effect listed in Table 4.3, load the REG_SOUND register with a code value and write 1 to
the REG_PLAY register. The REG_PLAY register reads 1 while the effect is playing and returns a ‘0’ when
the effect ends. Some sound effects play continuously until interrupted or instructed to play the next
sound effect. To interrupt an effect, write a new value to REG_SOUND and REG_PLAY registers; e.g. write
0 (Silence) to REG_SOUND and 1 to PEG_PLAY to stop the sound effect.
The sound volume is controlled by register REG_VOL_SOUND. The 16-bit REG_SOUND register takes an
8-bit sound in the low byte. For some sounds, marked "pitch adjust" in the table below, the high 8 bits
contain a MIDI note value. For these sounds, a note value of zero indicates middle C. For other sounds
the high byte of REG_SOUND is ignored.
Value
Effect
Continu
ous
Pitch
adjust
Value
Effect
Continu
ous
Pitch
adjust
00h
Silence
Y
N
32h
DTMF 2
Y
N
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01h
square wave
Y
Y
33h
DTMF 3
Y
N
02h
sine wave
Y
Y
34h
DTMF 4
Y
N
03h
sawtooth wave
Y
Y
35h
DTMF 5
Y
N
04h
triangle wave
Y
Y
36h
DTMF 6
Y
N
05h
Beeping
Y
Y
37h
DTMF 7
Y
N
06h
Alarm
Y
Y
38h
DTMF 8
Y
N
07h
Warble
Y
Y
39h
DTMF 9
Y
N
08h
Carousel
Y
Y
40h
harp
N
Y
10h
1 short pip
N
Y
41h
xylophone
N
Y
11h
2 short pips
N
Y
42h
tuba
N
Y
12h
3 short pips
N
Y
43h
glockenspiel
N
Y
13h
4 short pips
N
Y
44h
organ
N
Y
14h
5 short pips
N
Y
45h
trumpet
N
Y
15h
6 short pips
N
Y
46h
piano
N
Y
16h
7 short pips
N
Y
47h
chimes
N
Y
17h
8 short pips
N
Y
48h
music box
N
Y
18h
9 short pips
N
Y
49h
bell
N
Y
19h
10 short pips
N
Y
50h
click
N
N
1Ah
11 short pips
N
Y
51h
switch
N
N
1Bh
12 short pips
N
Y
52h
cowbell
N
N
1Ch
13 short pips
N
Y
53h
notch
N
N
1Dh
14 short pips
N
Y
54h
hihat
N
N
1Eh
15 short pips
N
Y
55h
kickdrum
N
N
1Fh
16 short pips
N
Y
56h
pop
N
N
23h
DTMF #
Y
N
57h
clack
N
N
2Ch
DTMF *
Y
N
58h
chack
N
N
30h
DTMF 0
Y
N
60h
mute
N
N
31h
DTMF 1
Y
N
61h
unmute
N
N
Table 4-15 Sound Effect
MIDI
note
ANSI
note
Freq (Hz)
MIDI
note
ANSI
note
Freq (Hz)
21
A0
27.5
65
F4
349.2
22
A#0
29.1
66
F#4
370.0
23
B0
30.9
67
G4
392.0
24
C1
32.7
68
G#4
415.3
25
C#1
34.6
69
A4
440.0
26
D1
36.7
70
A#4
466.2
27
D#1
38.9
71
B4
493.9
28
E1
41.2
72
C5
523.3
29
F1
43.7
73
C#5
554.4
30
F#1
46.2
74
D5
587.3
31
G1
49.0
75
D#5
622.3
32
G#1
51.9
76
E5
659.3
33
A1
55.0
77
F5
698.5
34
A#1
58.3
78
F#5
740.0
35
B1
61.7
79
G5
784.0
36
C2
65.4
80
G#5
830.6
37
C#2
69.3
81
A5
880.0
38
D2
73.4
82
A#5
932.3
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39
D#2
77.8
83
B5
987.8
40
E2
82.4
84
C6
1046.5
41
F2
87.3
85
C#6
1108.7
42
F#2
92.5
86
D6
1174.7
43
G2
98.0
87
D#6
1244.5
44
G#2
103.8
88
E6
1318.5
45
A2
110.0
89
F6
1396.9
46
A#2
116.5
90
F#6
1480.0
47
B2
123.5
91
G6
1568.0
48
C3
130.8
92
G#6
1661.2
49
C#3
138.6
93
A6
1760.0
50
D3
146.8
94
A#6
1864.7
51
D#3
155.6
95
B6
1975.5
52
E3
164.8
96
C7
2093.0
53
F3
174.6
97
C#7
2217.5
54
F#3
185.0
98
D7
2349.3
55
G3
196.0
99
D#7
2489.0
56
G#3
207.7
100
E7
2637.0
57
A3
220.0
101
F7
2793.8
58
A#3
233.1
102
F#7
2960.0
59
B3
246.9
103
G7
3136.0
60
C4
261.6
104
G#7
3322.4
61
C#4
277.2
105
A7
3520.0
62
D4
293.7
106
A#7
3729.3
63
D#4
311.1
107
B7
3951.1
64
E4
329.6
108
C8
4186.0
Table 4-16 MIDI Note Effect
4.6.2 Audio Playback
The FT81x can play back recorded sound through its audio output. To do this, load the original sound
data into the FT81x’s RAM, and set registers to start the playback.
The registers controlling audio playback are:
REG_PLAYBACK_START: the start address of the audio data
REG_PLAYBACK_LENGTH: the length of the audio data, in bytes
REG_PLAYBACK_FREQ: the playback sampling frequency, in Hz
REG_PLAYBACK_FORMAT: the playback format, one of LINEAR SAMPLES, uLAW
SAMPLES, or ADPCM SAMPLES
REG_PLAYBACK_LOOP: if zero, the sample is played once. If one, the sample is repeated
indefinitely
REG_PLAYBACK_PLAY: a write to this location triggers the start of audio playback,
regardless of writing ‘0’ or ‘1’. Read back ‘1’ when playback
is ongoing, and ‘0’ when playback finishes
REG_VOL_PB: playback volume, 0-255
The mono audio formats supported are 8-bits PCM, 8-bits uLAW and 4-bits IMA-ADPCM. For
ADPCM_SAMPLES, each sample is 4 bits, so two samples are packed per byte, the first sample is in bits
0-3 and the second is in bits 4-7.
The current audio playback read pointer can be queried by reading the REG_PLAYBACK_READPTR. Using
a large sample buffer, looping, and this read pointer, the host MPU/MCU can supply a continuous stream
of audio.
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4.7 Touch-Screen Engine
The FT81x touch-screen engine supports both resistive and capacitive touch panels. FT810 and FT812
support resistive touch, while FT811 and FT813 support capacitive touch.
4.7.1 Resistive Touch Control
The resistive touch-screen consists of a touch screen engine, ADC, Axis-switches, and ADC input
multiplexer. The touch screen engine reads commands from the memory map register and generates the
required control signals to the axis-switches and inputs mux and ADC. The ADC data are acquired,
processed and updated in the respective register for the MPU/MCU to read.
Figure 4-8 Resistive Touch screen connection
The host controls the TOUCH SCREEN ENGINE operation mode by writing the REG_TOUCH_MODE.
REG_TOUCH_MODE
Mode
Description
0
OFF
Acquisition stopped, only touch detection interrupt is still valid.
1
ONE-SHOT
Perform acquisition once every time the MPU writes '1' to
REG_TOUCH_MODE.
2
FRAME-SYNC
Perform acquisition for every frame sync (~60 data
acquisition/second.
3
CONTINUOUS
Perform acquisition continuously at approximately 1000 data
acquisition / second.
Table 4-17 Resistive Touch Controller Operating Mode
The Touch Screen Engine captures the raw X and Y coordinate and writes to register REG_TOUCH_RAW
XY. The range of these values is 0-1023. If the touch screen is not being pressed, both registers read
65535 (FFFFh).
These touch values are transformed into screen coordinates using the matrix in registers
REG_TOUCH_TRANSFORM_A-F. The post-transform coordinates are available in register
REG_TOUCH_SCREEN_XY. If the touch screen is not being pressed, both registers read -32768 (8000h).
The values for REG TOUCH TRANSFORM A-F may be computed using an on-screen calibration process.
Y+
Y-
X-
X+
FT810/
FT812
XP
YP
XM
YM
Resistive Touch Screen
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If the screen is being touched, the screen coordinates are looked up in the screen's tag buffer, delivering
a final 8-bit tag value, in REG TOUCH TAG. Because the tag lookup takes a full frame, and touch
coordinates change continuously, the original (x; y) used for the tag lookup is also available in
REG_TOUCH_TAG_XY.
Screen touch pressure is available in REG_TOUCH_RZ. The value is relative to the resistance of the touch
contact, a lower value indicates more pressure. The register defaults to 32767 when touch is not
detected. The REG_TOUCH_THRESHOLD can be set to accept a touch only when the force threshold is
exceeded.
4.7.2 Capacitive Touch Control
The Capacitive Touch Screen Engine (CTSE) of the FT81x communicates with the external capacitive
touch panel module (CTPM) through an I2C interface. The CTPM will assert its interrupt line when there is
a touch detected. Upon detecting CTP_INT_N line active, the FT81x will read the touch data through I2C.
Up to 5 touches can be reported and stored in FT81x registers.
For a supported CTPM list please consult FTDI website.
Figure 4-9 Touch screen connection
The host controls the CTSE operation mode by writing the REG_CTOUCH_MODE.
REG_CTOUCH_MODE
Mode
Description
0
OFF
Acquisition stopped
1-2
Reserved
Reserved
3
CONTINUOUS
Perform acquisition continuously at the reporting rate of the
connected CTPM.
Table 4-18 Capacitive Touch Controller Operating Mode
The FT81x CTSE supports compatibility mode and extended mode. By default the CTSE runs in
compatibility mode where the touch system provides an interface very similar to the resistive touch
engine. In this mode the same application code can run on FT810/FT812 and FT811/FT813 without
alteration. In extended mode, the touch register meanings are modified, and a second set of registers are
exposed. These allow multi-touch detection (up to 5 touches).
SCL
RSTN
SDA
INTN
FT811/
FT813
CTP_SCL
CTP_SDA
CTP_INT_N
CTP_RST_N
Capacitive Touch
Panel Module
VCCIO2
(1.8-3.3V)
1K
1K
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4.7.3 Compatibility mode
The CTSE reads the X and Y coordinates from the CTPM and writes to register REG_CTOUCH_RAW_XY. If
the touch screen is not being pressed, both registers read 65535 (FFFFh).
These touch values are transformed into screen coordinates using the matrix in registers
REG_CTOUCH_TRANSFORM_A-F. The post-transform coordinates are available in register
REG_CTOUCH_SCREEN_XY. If the touch screen is not being pressed, both registers read -32768 (8000h).
The values for REG_CTOUCH_TRANSFORM_A-F may be computed using an on-screen calibration process.
If the screen is being touched, the screen coordinates are looked up in the screen's tag buffer, delivering
a final 8-bit tag value, in REG_TOUCH_TAG. Because the tag lookup takes a full frame, and touch
coordinates change continuously, the original (x; y) used for the tag lookup is also available in
REG_TOUCH_TAG_XY.
4.7.4 Extended mode
Setting REG_CTOUCH_EXTENDED to 1b’0 enables extended mode. In extended mode a new set of
readout registers are available, allowing gestures and up to five touches to be read. There are two
classes of registers: control registers and status registers. Control registers are written by the MCU.
Status registers can be read out by the MCU and the FT81x’s hardware tag system.
The five touch coordinates are packed in REG_CTOUCH_TOUCH0_XY, REG_CTOUCH_TOUCH1_XY,
REG_CTOUCH_TOUCH2_XY, REG_CTOUCH_TOUCH3_XY, REG_CTOUCH4_X and REG_CTOUCH4_Y.
Coordinates stored in these registers are signed 16-bit values, so have range -32768 to 32767. The no-
touch condition is indicated by x=y= -32768. These coordinates are already transformed into screen
coordinates based on the raw data read from the CTPM, using the matrix in registers
REG_CTOUCH_TRANSFORM_A-F. To obtain raw (x,y) coordinates read from CTPM, the user sets the
REG_CTOUCH_TRANSFORM_A-F registers to the identity matrix.
The FT81x tag mechanism is implemented by hardware, where up to 5 tags can be looked up.
4.7.5 Short-circuit protection
For resistive touch it is useful to protect the chip from permanent damage due to potential short-circuits
on the 4 XY lines. When a short circuit on the touch screen happens, the FT81x can detect it and stop the
touch detection operation, leaving the 4 XY pins in the high impedance state.
The short-circuit protection can be enabled/disabled by the REG_TOUCH_CONFIG.
4.7.6 Capacitive touch configuration
On capacitive touch system some users may need to adjust the CTPM default values, such as the
registers affecting touch sensitivity. To do this the following sequence shall be executed once after chip
reset:
- Hold the touch engine in reset (set REG_CPURESET = 2)
- Write the CTPM configure register address and value to FT81x designated memory location
- Up to 10 register address/value can be added
- Release the touch engine reset (set REG_CPURESET = 0)
The CTPM can be enabled in low power state when the touch function is not required by the application.
Setting the low-power bit in REG_TOUCH_CONFIG will enable the low power mode of the CTPM. When
the low-power bit is cleared, the FT81x touch engine will send a reset to the CTPM, thus re-enabling the
touch detection function.
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4.7.7 Touch detection in none-ACTIVE state
When FT81x is in none-ACTIVE state, a touch event can still be detected and reported to the host
through the INT_N pin. In other words, a touch event can wake-up the host if needed.
For resistive touch, the INT_N pin will be asserted low when the screen is touched, regardless of the
setting of the interrupt registers. This will happen when the FT81x is in STANDBY or SLEEP state, but not
in POWERDOWN state.
For capacitive touch, the INT_N pin will follow CTP_INT_N pin when the FT81x is in STANDBY, SLEEP or
POWERDOWN state.
4.8 Power Management
4.8.1 Power supply
The FT81x may be operated with a single supply of 3.3V applied to VCC and VCCIO pins. For operation
with a host MPU/MCU at a lower supply, connect the VCCIO1 to the MPU IO supply to match the interface
voltage. For operation with LCD/touch panels at lower voltages, connect the VCCIO2 to the LCD/touch IO
supply.
Symbol
Typical
Description
VCCIO1
1.8V, or 2.5V, or 3.3V
Supply for Host interface digital I/O pins
VCCIO2
1.8V, or 2.5V, or 3.3V
Supply for RGB and touch interface I/O pins
VCC
3.3V
Supply for 3.3V circuits and internal regulator
VOUT1V2
1.2V
Supply for digital core. Generated by internal regulator
Table 4-19 Power supply
4.8.2 Internal Regulator and POR
The internal regulator provides power to the core circuit. A 47kΩ resistor is recommended to pull the
PD_N pin up to VCCIO1, together with a 100nF capacitor to ground in order to delay the internal
regulator powering up after the VCC and VCCIO are stable.
The internal regulator requires a compensation capacitor to be stable. A typical design requires a 4.7uF
capacitor between the VOUT1V2 and GND pins. Do not connect any other load to the VOUT1V2 pin.
The internal regulator will generate a Power-On-Reset (POR) pulse when the output voltage rises above
the POR threshold. The POR will reset all the core digital circuits.
It is possible to use PD_N pin as an asynchronous hardware reset input. Drive PD_N low for at least 5ms
and then drive it high will reset the FT81x chip.
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Figure 4-10 Internal regulator
4.8.3 Power Modes
When the supply to VCCIO and VCC is applied, the internal regulator is powered by VCC. An internal POR
pulse will be generated during the regulator power up until it is stable. After the initial power up, the
FT81x will stay in the SLEEP state. When needed, the host can set the FT81x to the ACTIVE state by
performing a SPI ACTIVE command. The graphics engine, the audio engine and the touch engine are only
functional in the ACTIVE state. To save power the host can send a command to put the FT81x into any of
the low power modes: STANDBY, SLEEP and POWERDOWN. In addition, the host is allowed to put the
FT81x in POWERDOWN mode by driving the PD_N pin to low, regardless of what state it is currently in.
Refer to Figure 4-11 for the power state transitions.
VCC
PD_N
G
N
D
VOUT1V2
VCC
GND
GND
GND
VCCIO1
C1
R1
C2
10uF
100nF
GND
C3
4.7uF
47k
FT81x
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Figure 4-11 Power State Transition
4.8.3.1 ACTIVE state
In ACTIVE state, the FT81x is in normal operation. The clock oscillator and PLL are functioning. The
system clock applied to the FT81x core engines is enabled.
4.8.3.2 STANDBY state
In STANDBY state, the clock oscillator and PLL remain functioning; the system clock applied to the FT81x
core engines is disabled. All register contents are retained.
4.8.3.3 SLEEP state
In SLEEP state, the clock oscillator, PLL and system clock applied to the FT81x core engines are disabled.
All register contents are retained.
4.8.3.4 POWERDOWN state
In POWERDOWN state, the clock oscillator, the PLL and the system clock applied to the FT81x core is
disabled. The core engines are powered down while the SPI interface for host commands remains
functional. All register contents are lost and reset to default when the chip is next switched on. The
internal regulator remains on.
4.8.3.5 Wake up to ACTIVE from other power states
When in the POWER DOWN state, if the device enters this state via an SPI command, then only the SPI
ACTIVE command will bring the device back to the ACTIVE state, provided PD_N pin is also high.
However, if PD_N is used instead, then making PD_N high followed by a SPI ACTIVE command will wake
up the device. Upon exiting this state, the device will perform a global reset, and will go through the
same power up sequence. All settings from SPI commands will be reset except those that pertain to pin
states during power down. The clock enable sequence mentioned in section 4.2.3 shall be executed to
properly select and enable the system clock.
POWERDOWN
SLEEP
STANDBY
VCC/VCCIO
Power ON
Toggle PD_N from high
to low
ACTIVE
Toggle PD_N from low
to high
Toggle PD_N from high
to low
Toggle PD_N from high to low or
Write command “POWERDOWN”
Write command “STANDBY”
Write command
“SLEEP”
Write command
“ACTIVE”
Write command
“ACTIVE”
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From the SLEEP state, the host MPU sends an SPI ACTIVE command to wake the FT81x into the ACTIVE
state. The host needs to wait for at least 20ms before accessing any registers or commands. This is to
guarantee the clock oscillator and PLL are up and stable.
From the STANDBY state, the host MPU sends SPI ACTIVE command to wake the FT81x into the ACTIVE
state. The host can immediately access any register or command.
4.8.4 Reset and boot-up sequence
There are a few hardware and software reset events which can be triggered to reset the FT81x.
Hardware reset events:
Power-on-Reset(POR)
Toggle the PD_N pin
Software reset events:
SPI command RST_PULSE
SPI command to switch between the internal clock and the external clock
SPI command to enter POWERDOWN then wakeup
After reset the FT81x will be in the SLEEP state. Upon receiving an SPI ACTIVE command, the internal
oscillator and PLL will start up. Once the clock is stable, the chip will check and repair its internal RAM,
running the configuration and release the clock to the system. The chip will exit the reset and boot-up
state and enter into normal operations. The boot-up may take up to 300ms to complete.
4.8.5 Pin Status at Different Power States
The FT81x pin status depends on the power state of the chip. See the following table for more details. At
the power transition from ACTIVE to STANDBY or ACTIVE to SLEEP, all pins retain their previous status.
The software needs to set AUDIO_L, BACKLIGHT to a known state before issuing power transition
commands.
The pin status in the power down state can be changed by SPI command PIN_PD_STATE.
Pin Name
Default Drive
Reset
Normal
Power Down
(Default)
AUDIO_L
20mA
Out, Float
Out
Pull Low
SCK
-
In
In
In
MISO
5mA
Out, Float
(CS_N = 1)
IO
Out, Float
MOSI
5mA
In
IO
In
CS_N
-
In
In
In
IO2
GPIO0
5mA
5mA
In
In
IO
IO
Float
Float
IO3
GPIO1
5mA
5mA
In
In
IO
IO
Float
Float
GPIO2
5mA
In
IO
Float
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Pin Name
Default Drive
Reset
Normal
Power Down
(Default)
INT_N
5mA
OD, Float
OD / Out
Float
PD_N
-
In
In
In
GPIO3
5mA
In
IO
Float
X1/CLK
-
In
In
In
XP
-
IO, Float
IO
Float
YP
-
IO, Float
IO
Float
XM
-
IO, Float
IO
Float
YM
-
IO, Float
IO
Float
CTP_RST_N
5mA
Out
Out
Pull Low
CTP_INT_N
-
In (internal
pull-up)
In (internal
pull-up)
In (internal
pull-up)
CTP_SCL
20mA
OD
IO
Float
CTP_SDA
20mA
OD
IO
Float
BACKLIGHT
5mA
Out
Out
Pull Low
DE
5mA
Out
Out
Pull Low
VSYNC
5mA
Out
Out
Pull Low
HSYNC
5mA
Out
Out
Pull Low
DISP
5mA
Out
Out
Pull Low
PCLK
5mA
Out
Out
Pull Low
R/G/B
5mA
Out
Out
Pull Low
Table 4-20 Pin Status
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5 Memory Map
All memory and registers in the FT81x core are memory mapped in 22-bit address space with a 2-bit SPI
command prefix. Prefix 0'b00 for read and 0'b10 for write to the address space, 0'b01 is reserved for
Host Commands and 0'b11 undefined. The following are the memory space definition.
Start
Address
End
Address
Size
NAME
Description
00 0000h
0F FFFFh
1024 kB
RAM_G
General purpose graphics RAM
1E 0000h
2F FFFBh
1152 kB
ROM_FONT
Font table and bitmap
2F FFFCh
2F FFFFh
4 B
ROM_FONT_ADDR
Font table pointer address
30 0000h
30 1FFFh
8 kB
RAM_DL
Display List RAM
30 2000h
30 2FFFh
4 kB
RAM_REG
Registers
30 8000h
30 8FFFh
4 kB
RAM_CMD
Command buffer
Table 5-1 FT81x Memory Map
Note 1: The addresses beyond this table are reserved and shall not be read or written unless otherwise
specified.
5.1 Registers
The tableError! Reference source not found. shows the complete list of the FT81x registers. Refer to
FT81x_Series_Programmers_Guide, Chapter 2 for details of the register function.
Address
(hex)
Register Name
Bit
s
r/
w
Reset
value
Description
302000h
REG_ID
8
r/o
7Ch
Identification register, always reads as
7Ch
302004h
REG_FRAMES
32
r/o
0
Frame counter, since reset
302008h
REG_CLOCK
32
r/o
0
Clock cycles, since reset
30200Ch
REG_FREQUENCY
28
r/w
60000000
Main clock frequency (Hz)
302010h
REG_RENDERMODE
1
r/w
0
Rendering mode: 0 = normal, 1 = single-
line
302014h
REG_SNAPY
11
r/w
0
Scanline select for RENDERMODE 1
302018h
REG_SNAPSHOT
1
r/w
-
Trigger for RENDERMODE 1
30201Ch
REG_SNAPFORMAT
6
r/w
20h
Pixel format for scanline readout
302020h
REG_CPURESET
3
r/w
2
Graphics, audio and touch engines reset
control. Bit2: audio, bit1: touch, bit0:
graphics
302024h
REG_TAP_CRC
32
r/o
-
Live video tap crc. Frame CRC is
computed every DL SWAP.
Copyright © Bridgetek Pte Ltd 42
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Address
(hex)
Register Name
Bit
s
r/
w
Reset
value
Description
302028h
REG_TAP_MASK
32
r/w
FFFFFFFFh
Live video tap mask
30202Ch
REG_HCYCLE
12
r/w
224h
Horizontal total cycle count
302030h
REG_HOFFSET
12
r/w
02Bh
Horizontal display start offset
302034h
REG_HSIZE
12
r/w
1E0h
Horizontal display pixel count
302038h
REG_HSYNC0
12
r/w
000h
Horizontal sync fall offset
30203Ch
REG_HSYNC1
12
r/w
029h
Horizontal sync rise offset
302040h
REG_VCYCLE
12
r/w
124h
Vertical total cycle count
302044h
REG_VOFFSET
12
r/w
00Ch
Vertical display start offset
302048h
REG_VSIZE
12
r/w
110h
Vertical display line count
30204Ch
REG_VSYNC0
10
r/w
000h
Vertical sync fall offset
302050h
REG_VSYNC1
10
r/w
00Ah
Vertical sync rise offset
302054h
REG_DLSWAP
2
r/w
0
Display list swap control
302058h
REG_ROTATE
3
r/w
0
Screen rotation control. Allow
normal/mirrored/inverted for landscape
or portrait orientation.
30205Ch
REG_OUTBITS
9
r/w
1B6h/000h
Output bit resolution, 3 bits each for
R/G/B. Default is 6/6/6 bits for
FT810/FT811, and 8/8/8 bits for
FT812/FT813 (0b’000 means 8 bits)
302060h
REG_DITHER
1
r/w
1
Output dither enable
302064h
REG_SWIZZLE
4
r/w
0
Output RGB signal swizzle
302068h
REG_CSPREAD
1
r/w
1
Output clock spreading enable
30206Ch
REG_PCLK_POL
1
r/w
0
PCLK polarity:
0 = output on PCLK rising edge,
1 = output on PCLK falling edge
302070h
REG_PCLK
8
r/w
0
PCLK frequency divider, 0 = disable
302074h
REG_TAG_X
11
r/w
0
Tag query X coordinate
302078h
REG_TAG_Y
11
r/w
0
Tag query Y coordinate
30207Ch
REG_TAG
8
r/o
0
Tag query result
302080h
REG_VOL_PB
8
r/w
FFh
Volume for playback
302084h
REG_VOL_SOUND
8
r/w
FFh
Volume for synthesizer sound
302088h
REG_SOUND
16
r/w
0
Sound effect select
30208Ch
REG_PLAY
1
r/w
0h
Start effect playback
Copyright © Bridgetek Pte Ltd 43
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Address
(hex)
Register Name
Bit
s
r/
w
Reset
value
Description
302090h
REG_GPIO_DIR
8
r/w
80h
Legacy GPIO pin direction,
0 = input , 1 = output
302094h
REG_GPIO
8
r/w
00h
Legacy GPIO read/write
302098h
REG_GPIOX_DIR
16
r/w
8000h
Extended GPIO pin direction,
0 = input , 1 = output
30209Ch
REG_GPIOX
16
r/w
0080h
Extended GPIO read/write
3020A0h-
3020A4h
Reserved
-
-
-
Reserved
3020A8h
REG_INT_FLAGS
8
r/o
00h
Interrupt flags, clear by read
3020Ach
REG_INT_EN
1
r/w
0
Global interrupt enable, 1=enable
3020B0h
REG_INT_MASK
8
r/w
FFh
Individual interrupt enable, 1=enable
3020B4h
REG_PLAYBACK_START
20
r/w
0
Audio playback RAM start address
3020B8h
REG_PLAYBACK_LENGTH
20
r/w
0
Audio playback sample length (bytes)
3020BCh
REG_PLAYBACK_READPTR
20
r/o
-
Audio playback current read pointer
3020C0h
REG_PLAYBACK_FREQ
16
r/w
8000
Audio playback sampling frequency (Hz)
3020C4h
REG_PLAYBACK_FORMAT
2
r/w
0
Audio playback format
3020C8h
REG_PLAYBACK_LOOP
1
r/w
0
Audio playback loop enable
3020CCh
REG_PLAYBACK_PLAY
1
r/w
0
Start audio playback
3020D0h
REG_PWM_HZ
14
r/w
250
BACKLIGHT PWM output frequency (Hz)
3020D4h
REG_PWM_DUTY
8
r/w
128
BACKLIGHT PWM output duty cycle
0=0%, 128=100%
3020D8h
REG_MACRO_0
32
r/w
0
Display list macro command 0
3020DCh
REG_MACRO_1
32
r/w
0
Display list macro command 1
3020E0h –
3020F4h
Reserved
-
-
-
Reserved
3020F8h
REG_CMD_READ
12
r/w
0
Command buffer read pointer
3020FCh
REG_CMD_WRITE
12
r/o
0
Command buffer write pointer
302100h
REG_CMD_DL
13
r/w
0
Command display list offset
302104h
REG_TOUCH_MODE
2
r/w
3
Touch-screen sampling mode
302108h
REG_TOUCH_ADC_MODE
REG_CTOUCH_EXTENDED
1
r/w
1
Set Touch ADC mode
Set capacitive touch operation mode:
0: extended mode (multi-touch)
1: FT800 compatibility mode (single
Copyright © Bridgetek Pte Ltd 44
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Address
(hex)
Register Name
Bit
s
r/
w
Reset
value
Description
touch).
30210Ch
REG_TOUCH_CHARGE
16
r/w
9000
Touch charge time, units of 6 clocks
302110h
REG_TOUCH_SETTLE
4
r/w
3
Touch settle time, units of 6 clocks
302114h
REG_TOUCH_OVERSAMPLE
4
r/w
7
Touch oversample factor
302118h
REG_TOUCH_RZTHRESH
16
r/w
FFFFh
Touch resistance threshold
30211Ch
REG_TOUCH_
RAW_XY
REG_CTOUCH_TOUCH1_XY
32
r/o
-
Compatibility mode: touch-screen raw (x-
MSB16; y-LSB16)
Extended mode: touch-screen screen
data for touch 1 (x-MSB16; y-LSB16)
302120h
REG_TOUCH_RZ
REG_CTOUCH_TOUCH4_Y
16
r/o
-
Compatibility mode: touch-screen
resistance
Extended mode: touch-screen screen Y
data for touch 4
302124h
REG_TOUCH_
SCREEN_XY
REG_CTOUCH_TOUCH0_XY
32
r/o
-
Compatibility mode: touch-screen screen
(x-MSB16; y-LSB16)
Extended mode: touch-screen screen
data for touch 0 (x-MSB16; y-LSB16)
302128h
REG_TOUCH_
TAG_XY
32
r/o
-
Touch-screen screen (x-MSB16; y-
LSB16) used for tag 0 lookup
30212Ch
REG_TOUCH_TAG
8
r/o
-
Touch-screen tag result 0
302130h
REG_TOUCH_
TAG1_XY
32
r/o
-
Touch-screen screen (x-MSB16; y-
LSB16) used for tag 1 lookup
302134h
REG_TOUCH_TAG1
8
r/o
-
Touch-screen tag result 1
302138h
REG_TOUCH_
TAG2_XY
32
r/o
-
Touch-screen screen (x-MSB16; y-
LSB16) used for tag 2 lookup
30213Ch
REG_TOUCH_TAG2
8
r/o
-
Touch-screen tag result 2
302140h
REG_TOUCH_
TAG3_XY
32
r/o
-
Touch-screen screen (x-MSB16; y-
LSB16) used for tag 3 lookup
302144h
REG_TOUCH_TAG3
8
r/o
-
Touch-screen tag result 3
302148h
REG_TOUCH_
TAG4_XY
32
r/o
-
Touch-screen screen (x-MSB16; y-
LSB16) used for tag 4 lookup
30214Ch
REG_TOUCH_TAG4
8
r/o
-
Touch-screen tag result 4
302150h
REG_TOUCH_TRANSFORM_A
32
r/w
00010000h
Touch-screen transform coefficient
(s15.16)
Copyright © Bridgetek Pte Ltd 45
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Address
(hex)
Register Name
Bit
s
r/
w
Reset
value
Description
302154h
REG_TOUCH_TRANSFORM_B
32
r/w
00000000h
Touch-screen transform coefficient
(s15.16)
302158h
REG_TOUCH_TRANSFORM_C
32
r/w
00000000h
Touch-screen transform coefficient
(s15.16)
30215Ch
REG_TOUCH_TRANSFORM_D
32
r/w
00000000h
Touch-screen transform coefficient
(s15.16)
302160h
REG_TOUCH_TRANSFORM_E
32
r/w
00010000h
Touch-screen transform coefficient
(s15.16)
302164h
REG_TOUCH_TRANSFORM_F
32
r/w
00000000h
Touch-screen transform coefficient
(s15.16)
302168h
REG_TOUCH_CONFIG
16
r/w
8381h(FT81
0/FT812)
0381h(FT81
1/FT813)
Touch configuration.
RTP/CTP select
RTP: short-circuit, sample clocks
CTP: I2C address, CTPM type, low-power
mode
30216Ch
REG_CTOUCH_TOUCH4_X
16
r/o
-
Extended mode: touch-screen screen X
data for touch 4
302170h
Reserved
-
-
-
Reserved
302174h
REG_BIST_EN
1
r/w
0
BIST memory mapping enable
302178h
Reserved
-
-
-
Reserved
30217Ch
Reserved
-
-
-
Reserved
302180h
REG_TRIM
8
r/w
0
Internal relaxation clock trimming
302184h
REG_ANA_COMP
8
r/w
0
Analogue control register
Copyright © Bridgetek Pte Ltd 46
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Address
(hex)
Register Name
Bit
s
r/
w
Reset
value
Description
302188h
REG_SPI_WIDTH
3
r/w
0
QSPI bus width setting
Bit [2]: extra dummy cycle on read
Bit [1:0]: bus width (0=1-bit, 1=2-bit,
2=4-bit)
30218Ch
REG_TOUCH_DIRECT_XY
REG_CTOUCH_TOUCH2_XY
32
r/o
-
Compatibility mode: Touch screen direct
(x-MSB16; y-LSB16) conversions
Extended mode: touch-screen screen
data for touch 2 (x-MSB16; y-LSB16)
302190h
REG_TOUCH_DIRECT_Z1Z2
REG_CTOUCH_TOUCH3_XY
32
r/o
-
Compatibility mode: Touch screen direct
(z1-MSB16; z2-LSB16) conversions
Extended mode: touch-screen screen
data for touch 3 (x-MSB16; y-LSB16)
302194h-
302560h
Reserved
-
-
-
Reserved
302564h
REG_DATESTAMP
128
r/o
-
Stamp date code
302574h
REG_CMDB_SPACE
12
r/w
FFCh
Command DL (bulk) space available
302578h
REG_CMDB_WRITE
32
w/o
0
Command DL (bulk) write
Table 5-2 Overview of FT81x Registers
Note: All register addresses are 4-byte aligned. The value in the “Bits” column refers to the number of
valid bits from bit 0 unless otherwise specified; other bits are reserved.
5.2 Chip ID
The FT81x Chip ID can be read at memory location 0C0000h – 0C0003h. The reset values of these bytes
are:
- 0C0000h: 08h
- 0C0001h: 10h (FT810), 11h(FT811), 12h(FT812), 13h(FT813)
- 0C0002h: 01h
- 0C0003h: 00h
Note that the Chip ID location can be over-written by software.
Copyright © Bridgetek Pte Ltd 47
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
6 Devices Characteristics and Ratings
6.1 Absolute Maximum Ratings
The absolute maximum ratings for the FT81x device are as follows. These are in accordance with the
Absolute Maximum Rating System (IEC 60134). Exceeding these may cause permanent damage to the
device.
Parameter
Value
Unit
Storage Temperature
-65 to +150
°C
Floor Life (Out of Bag) At Factory Ambient
(30°C / 60% Relative Humidity)
168 (IPC/JEDEC J-STD-033A MSL Level 3
Compliant)*
Hours
Ambient Temperature (Power Applied)
-40 to +85
°C
VCC Supply Voltage
0 to +4
V
VCCIO Supply Voltage
0 to +4
V
DC Input Voltage
-0.5 to + (VCCIO + 0.3)
V
Table 6-1 Absolute Maximum Ratings
* If the devices are stored out of the packaging, beyond this time limit, the devices should be baked
before use. The devices should be ramped up to a temperature of +125°C and baked for up to 17 hours.
6.2 ESD and Latch-up Specifications
Description
Specification
Human Body Mode (HBM)
> ± 2kV
Machine mode (MM)
> ± 200V
Charged Device Mode (CDM)
> ± 500V
Latch-up
> ± 200mA
Table 6-2 ESD and Latch-Up Specifications
6.3 DC Characteristics
Parameter
Description
Minimum
Typical
Maximum
Units
Conditions
VCCIO1/
VCCIO2
VCCIO operating
supply voltage
1.62
1.80
1.98
V
Normal Operation
2.25
2.50
2.75
V
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FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Parameter
Description
Minimum
Typical
Maximum
Units
Conditions
2.97
3.30
3.63
V
VCC
VCC operating supply
voltage
2.97
3.30
3.63
V
Normal Operation
Icc1
Power Down current
-
0.17
-
mA
Power down mode
Icc2
Sleep current
-
0.76
-
mA
Sleep Mode
Icc3
Standby current
-
1.8
-
mA
Standby Mode
Icc4
Operating current
-
22
-
mA
Normal Operation
Table 6-3 Operating Voltage and Current
Parameter
Description
Minimum
Typical
Maximum
Units
Conditions
Voh
Output Voltage High
VCCIO-
0.4
-
-
V
Ioh=5mA
Vol
Output Voltage Low
-
-
0.4
V
Iol=5mA
Vih
Input High Voltage
2.0
-
-
V
Vil
Input Low Voltage
-
-
0.8
V
Vth
Schmitt Hysteresis
Voltage
0.22
-
0.3
V
Iin
Input leakage current
-10
-
10
uA
Vin = VCCIO or 0
Ioz
Tri-state output
leakage current
-10
-
10
uA
Vin = VCCIO or 0
Rpu
Pull-up resistor
-
42
-
kΩ
Rpd
Pull-down resistor
-
44
-
kΩ
Table 6-4 Digital I/O Pin Characteristics (VCCIO = +3.3V)
Parameter
Description
Minimum
Typical
Maximum
Units
Conditions
Voh
Output Voltage High
VCCIO-
0.4
-
-
V
Ioh=5mA
Vol
Output Voltage Low
-
-
0.4
V
Iol=5mA
Vih
Input High Voltage
1.7
-
-
V
-
Vil
Input Low Voltage
-
-
0.7
V
-
Vth
Schmitt Hysteresis
Voltage
0.2
-
0.3
V
-
Iin
Input leakage current
-10
-
10
uA
Vin = VCCIO or 0
Copyright © Bridgetek Pte Ltd 49
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Ioz
Tri-state output
leakage current
-10
-
10
uA
Vin = VCCIO or 0
Rpu
Pull-up resistor
-
57
-
kΩ
Rpd
Pull-down resistor
-
59
-
kΩ
Table 6-5 Digital I/O Pin Characteristics (VCCIO = +2.5V)
Parameter
Description
Minimum
Typical
Maximum
Units
Conditions
Voh
Output Voltage High
VCCIO-
0.4
-
-
V
Ioh=5mA
Vol
Output Voltage Low
-
-
0.4
V
Iol=5mA
Vih
Input High Voltage
1.2
-
-
V
-
Vil
Input Low Voltage
-
-
0.6
V
-
Vth
Schmitt Hysteresis
Voltage
0.17
-
0.3
V
-
Iin
Input leakage current
-10
-
10
uA
Vin = VCCIO or 0
Ioz
Tri-state output
leakage current
-10
-
10
uA
Vin = VCCIO or 0
Rpu
Pull-up resistor
-
90
-
kΩ
Rpd
Pull-down resistor
-
97
-
kΩ
Table 6-6 Digital I/O Pin Characteristics (VCCIO = +1.8V)
Parameter
Description
Minimum
Typical
Maximum
Units
Conditions
Rsw-on
X-,X+,Y- and Y+
Drive On resistance
-
6
10
Ω
VCCIO=3.3V
-
9
16
Ω
VCCIO=1.8V
Rsw-off
X-,X+,Y- and Y+
Drive Off resistance
10
-
-
MΩ
Rpu
Touch sense pull up
resistance
78
100
125
kΩ
Vth+
Touch Detection
rising-edge threshold
on XP pin
1.59
-
2.04
V
VCCIO=3.3V
0.58
-
0.68
V
VCCIO=1.8V
Vth-
Touch Detection
falling-edge threshold
on XP pin
1.23
-
1.55
V
VCCIO=3.3V
0.51
-
0.56
V
VCCIO=1.8V
Rl
X-axis and Y-axis
drive load resistance
200
-
-
Ω
Table 6-7 Touch Sense Characteristics
Copyright © Bridgetek Pte Ltd 50
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
6.4 AC Characteristics
6.4.1 System clock and reset
Parameter
Value
Units
Minimum
Typical
Maximum
Internal Relaxation Clock
Trimmed frequency
-
12
-
MHz
Frequency variation
-5.5
-
+5.5
%
Crystal
Frequency
-
12.000
-
MHz
X1/X2
Capacitance
-
-
10
pF
External clock input
Frequency
-
12.000
-
MHz
Duty cycle
45
50
55
%
Input voltage on
X1/CLK
-
3.3
-
V
Reset
Reset pulse on PD_N
5
ms
Table 6-8 System clock characteristics
6.4.2 SPI interface timing
Figure 6-1 SPI Interface Timing
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FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Parameter
Description
VCCIO=1.8V
VCCIO=2.5V
VCCIO=3.3V
Units
Min
Max
Min
Max
Min
Max
Tsclk
SPI clock period
(SINGLE/DUAL
mode)
33.3
33.3
33.3
ns
Tsclk
SPI clock period
(QUAD mode)
40
40
40
ns
Tsclkl
SPI clock low
duration
13
13
13
ns
Tsclkh
SPI clock high
duration
13
13
13
ns
Tsac
SPI access time
4
3.5
3
ns
Tisu
Input Setup
4
3.5
3
ns
Tih
Input Hold
0
0
0
ns
Tzo
Output enable delay
16
13
11
ns
Toz
Output disable delay
13
11
10
ns
Tod
Output data delay
15
12
11
ns
Tcsnh
CSN hold time
0
0
0
ns
Table 6-9 SPI Interface Timing Specification
6.4.3 RGB Interface Timing
Parameter
Description
Value
Units
Min
Typ
Max
Tpclk
Pixel Clock period
15.7
ns
Tpclkdc
Pixel Clock duty cycle
40
50
60
%
Td
Output delay relative to PCLK rising
edge (REG_PCLK_POL=0) or falling
edge (REG_PCLK_POL=1). Applied for
all the RGB output pins.
4
ns
Th
Output hold time relative to PCLK
rising edge (REG_PCLK_POL=0) or
falling edge (REG_PCLK_POL=1).
Applied for all the RGB output pins.
0.5
ns
Table 6-10 RGB interface timing characteristics
Copyright © Bridgetek Pte Ltd 52
FT81X Embedded Video Engine Datasheet
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Document No.: BRT_000002 Clearance No.: BRT#004
Figure 6-2 RGB Interface Timing
Copyright © Bridgetek Pte Ltd 53
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
7 Application Examples
Figure 7-1 FT812 application circuit
Figure 7-2 FT813 application circuit
GND
B0
B1
B2
B3
B4
B5
B6
B7
R0
R1
R2
R3
R4
R5
R6
R7
G0
G1
G2
G3
G4
G5
G6
G7
XP
YP
XM
YM
BL_PWM
PCLK
DISP
HSYNC
VSYNC
DE
GNDGND
Y1
12MHz
C8
18pF C7
18pF
C1
4.7uF
C6
0.1uF
GND
C2
0.1uF
D3V3 VOUT1V2
C4
0.1uF
GND
D3V3
C3
0.1uF
C5
0.1uF
R2
R3
R4
R5
R6
R7
G2
G3
G4
G5
G6
G7
B2
B3
B4
B5
B6
B7
R1 33R
R2 33R
R3 33R
R4 33R
R5 33R
R6 33R
R7 33R
R8 33R
R9 33R
R10 33R
R11 33R
R12 33R
R14 33R
R15 33R
R16 33R
R17 33R
R18 33R
R13 33R
R19 33R
R21 33R
R22 33R
R23 33R
R20 33R
R0
R1
G0
G1
B0
B1
R24 33R
R25 33R
R26 33R
R27 33R
R28 33R
R29 33R
PCLK
DISP
HSYNC
VSYNC
DE
LEDK
LEDA
GND
D3V3 1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
9
9
10
10
11
11
12
12
13
13
14
14
15
15
16
16
17
17
18
18
19
19
20
20
21
21
22
22
23
23
24
24
25
25
26
26
27
27
28
28
29
29
30
30
31
31
32
32
33
33
34
34
35
35
36
36
37
37
38
38
39
39
40
40
0
0
0
0J1
0.5B-40PBS
VLED-
VLED+
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
HSYNC
VSYNC
PCLK
DISP
NC
VDD
X1
Y1
X2
DE
GND
GND
Y2
R0
R1
R2
R3
R4
R5
R6
R7
G0
G1
G2
G3
G4
G5
G6
G7
B0
B1
B2
B3
B4
B5
B6
B7
GND
[Left]
[Right]
[Bottom]
[Top]
LCD1
YM
XM
YP
XP
AUD_PWM
SPI_INT#
SPI_PD#
SPI_IO3
SPI_IO2
SPI_CS#
SPI_MISO
SPI_MOSI
QSPI master
AUD_PD#
SPI_SCK
MCU AUDIO_L
3
GND
4
SCK
5
MISO/IO1
6
MOSI/IO0
7
CS_N
8
GPIO0/IO2
9
GPIO1/IO3
10
VCCIO1
11
GPIO2
12
INT_N
13
PD_N
14
X1/CLK
16
X2
17
GND
18
VCC
19
VOUT1V2
20
VCC
21
VCCIO2
22
XP
23
YP
24
XM
25
YM
26
GND
27
DE 29
VSYNC 30
HSYNC 31
DISP 32
PCLK 33
B7 34
B6 35
B5 36
B4 37
B3 38
B2 39
GND 42
G7 43
G6 44
G5 45
G4 46
G3 47
G2 48
R7 51
R6 52
R5 53
R4 54
R3 55
R2 56
GND EP
R1
1
R0
2
GPIO3
15
BACKLIGHT
28
B0 41
B1 40
G1 49
G0 50
U1
IC_FT812Q
GND
B0
B1
B2
B3
B4
B5
B6
B7
R0
R1
R2
R3
R4
R5
R6
R7
G0
G1
G2
G3
G4
G5
G6
G7
CTP_RST#
CTP_INT#
CTP_SCL
CTP_SDA
BL_PWM
PCLK
DISP
HSYNC
VSYNC
DE
GNDGND
Y1
12MHz
C8
18pF C7
18pF
C1
4.7uF
C6
0.1uF
GND
C2
0.1uF
D3V3 VOUT1V2
C4
0.1uF
GND
D3V3
C3
0.1uF
C5
0.1uF
R2
R3
R4
R5
R6
R7
G2
G3
G4
G5
G6
G7
B2
B3
B4
B5
B6
B7
R1 33R
R2 33R
R3 33R
R4 33R
R5 33R
R6 33R
R7 33R
R8 33R
R9 33R
R10 33R
R11 33R
R12 33R
R14 33R
R15 33R
R16 33R
R17 33R
R18 33R
R13 33R
R19 33R
R21 33R
R22 33R
R23 33R
R20 33R
R0
R1
G0
G1
B0
B1
R24 33R
R25 33R
R26 33R
R27 33R
R28 33R
R29 33R
PCLK
DISP
HSYNC
VSYNC
DE
LEDK
LEDA
GND
D3V3 1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
9
9
10
10
11
11
12
12
13
13
14
14
15
15
16
16
17
17
18
18
19
19
20
20
21
21
22
22
23
23
24
24
25
25
26
26
27
27
28
28
29
29
30
30
31
31
32
32
33
33
34
34
35
35
36
36
37
37
38
38
39
39
40
40
0
0
0
0J1
0.5B-40PBS
VLED-
VLED+
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
HSYNC
VSYNC
PCLK
DISP
NC
VDD
X1
Y1
X2
DE
GND
GND
Y2
R0
R1
R2
R3
R4
R5
R6
R7
G0
G1
G2
G3
G4
G5
G6
G7
B0
B1
B2
B3
B4
B5
B6
B7
GND
[Left]
[Right]
[Bottom]
[Top]
LCD1
AUD_PWM
SPI_INT#
SPI_PD#
SPI_IO3
SPI_IO2
SPI_CS#
SPI_MISO
SPI_MOSI
QSPI master
AUD_PD#
SPI_SCK
1
1
2
2
3
3
4
4
5
5
6
6
0
0
0
0
J2
CN_6Pin_FPC BottomGND
CTP_SDA
CTP_SCL
CTP_RST#
CTP_INT#
D3V3
R32
1k
R31
1k
R30
4.7k
MCU AUDIO_L
3
GND
4
SCK
5
MISO/IO1
6
MOSI/IO0
7
CS_N
8
GPIO0/IO2
9
GPIO1/IO3
10
VCCIO1
11
GPIO2
12
INT_N
13
PD_N
14
X1/CLK
16
X2
17
GND
18
VCC
19
VOUT1V2
20
VCC
21
VCCIO2
22
CTP_RST_N
23
CTP_INT_N
24
CTP_SCL
25
CTP_SDA
26
GND
27
DE 29
VSYNC 30
HSYNC 31
DISP 32
PCLK 33
B7 34
B6 35
B5 36
B4 37
B3 38
B2 39
GND 42
G7 43
G6 44
G5 45
G4 46
G3 47
G2 48
R7 51
R6 52
R5 53
R4 54
R3 55
R2 56
GND EP
R1
1
R0
2
GPIO3
15
BACKLIGHT
28
B0 41
B1 40
G1 49
G0 50
U1
FT813Q
Copyright © Bridgetek Pte Ltd 54
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Figure 7-3 Backlight drive circuit
Figure 7-4 Audio filter and amplifier circuit
GND
C22
0.22uF
R40
4.7k
C16
2.2nF
D1
1N4148
R44
10k
C17
10uF
C18
0.1uF
R45
1R6
LED Current Sense R45
ILED=95/1.6 = 60mA
LEDK
LEDA
BL_PWM
GND GND GNDGND GND
L1
NR3015T220M
VOUT 1
VIN
2
FB 6
EN
3
AGND
4
SW 7
PGND
8
EP
9
U3
MIC2289
D5V
AUD_PWM
SHDN
1
BYPASS
2
IN+
3IN-
4
VO+ 5
VDD 6
GND 7
VO- 8
GND 9
U2
TPA6205A1
C19
1uF
R41
10k/1%
R36
10k/1%
R42 20k/1%
R37 20k/1%
C20
0.47uF C21
0.22uF
AGND
R43
47k
R33 1k C12
4.7nF
R34 1k C13
4.7nF
R35 1k C14
4.7nF
AGND
AGND AGND
VDD_AUD
AUD_PD#
AGND
SP-
SP+
AGND
C10
0.1uF
VDD_AUD
C11
10nF
C9
100uF
AGNDGND
FB1
600R/1A
FB2
600R/1A
AGND AGND
C15 0.47uF
D3V3
SP1
1W/8Ohm
Copyright © Bridgetek Pte Ltd 55
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
8 Package Parameters
The FT81x is available in VQFN-48 and VQFN-56 packages. The package dimensions, markings and solder
reflow profile for all packages are described in following sections.
8.1 Part Markings
8.1.1 Top side
Notes:
1. YYWW = Date Code, where YY is year and WW is week number
2. Pre date code 1727 – company logo was FTDI
3. Marking alignment should be centre justified
4. Laser Marking should be used
5. All marking dimensions should be marked proportionally. Marking font should be using standard
font (Roman Simplex)
6. BRT part number will be either FT810Q, FT811Q, FT812Q, FT813Q as per device selected.
8.1.3 Bottom Side
No markings should be placed on the bottom side.
Copyright © Bridgetek Pte Ltd 56
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
8.2 VQFN-48 Package Dimensions
A
A1
A3
b
D
E
D2
E2
e
L
K
MIN.
0.80
0.00
0.20
5.15
5.15
0.35
0.20
NOM.
0.85
0.02
0.20
0.25
7.00
7.00
5.20
5.20
0.50
0.40
MAX.
0.90
0.05
0.30
5.25
5.25
0.45
All dimensions are in millimetres (mm)
Figure 8-1 VQFN-48 Package Dimensions
8.3 VQFN-56 Package Dimensions
A
A1
A3
b
D
E
D2
E2
e
L
K
MIN.
0.80
0.00
0.20
5.85
5.85
0.30
0.20
NOM.
0.85
0.02
0.20
0.25
8.00
8.00
5.90
5.90
0.50
0.40
MAX.
0.90
0.05
0.30
5.95
5.95
0.50
All dimensions are in millimetres (mm)
Figure 8-2 VQFN-56 Package Dimensions
8.4 Solder Reflow Profile
The FT81x is supplied in a Pb free VQFN-48 or VQFN-56 package. The recommended solder reflow profile
for the package is shown in Figure 8-3.
Copyright © Bridgetek Pte Ltd 57
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Figure 8-3 FT81x Solder Reflow Profile
The recommended values for the solder reflow profile are detailed inError! Reference source not
found.. Values are shown for both a completely Pb free solder process (i.e. the FT81x is used with Pb
free solder), and for a non-Pb free solder process (i.e. the FT81x is used with non-Pb free solder).
Profile Feature
Pb Free Solder Process
Non-Pb Free Solder Process
Average Ramp Up Rate (Ts to Tp)
3°C / second Max.
3°C / Second Max.
Preheat
- Temperature Min (Ts Min.)
- Temperature Max (Ts Max.)
- Time (ts Min to ts Max)
150°C
200°C
60 to 120 seconds
100°C
150°C
60 to 120 seconds
Time Maintained Above Critical Temperature
TL:
- Temperature (TL)
- Time (tL)
217°C
60 to 150 seconds
183°C 60 to 150 seconds
Peak Temperature (Tp)
260°C
240°C
Time within 5°C of actual Peak Temperature
(tp)
20 to 40 seconds
20 to 40 seconds
Ramp Down Rate
6°C / second Max.
6°C / second Max.
Time for T= 25°C to Peak Temperature, Tp
8 minutes Max.
6 minutes Max.
Table 8-1 Reflow Profile Parameter Values
Critical Zone: when
T is in the range
T to T
Temperature, T (Degrees C)
Time, t (seconds)
25 P
T = 25º C to T
tp
Tp
TL
t
Preheat
S
tL
Ramp Up Lp
Ramp
Down
T Max
S
T Min
S
Copyright © Bridgetek Pte Ltd 58
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
9 Contact Information
Head Quarters – Singapore
Branch Office – Taipei, Taiwan
Bridgetek Pte Ltd
178 Paya Lebar Road, #07-03
Singapore 409030
Tel: +65 6547 4827
Fax: +65 6841 6071
Bridgetek Pte Ltd, Taiwan Branch
2 Floor, No. 516, Sec. 1, Nei Hu Road, Nei Hu District
Taipei 114
Taiwan, R.O.C.
Tel: +886 (2) 8797 5691
Fax: +886 (2) 8751 9737
E-mail (Sales)
sales.apac@brtchip.com
E-mail (Sales)
sales.apac@brtchip.com
E-mail (Support)
support.apac@brtchip.com
E-mail (Support)
support.apac@brtchip.com
Branch Office - Glasgow, United Kingdom
Branch Office – Vietnam
Bridgetek Pte. Ltd.
Unit 1, 2 Seaward Place, Centurion Business Park
Glasgow G41 1HH
United Kingdom
Tel: +44 (0) 141 429 2777
Fax: +44 (0) 141 429 2758
Bridgetek VietNam Company Limited
Lutaco Tower Building, 5th Floor, 173A Nguyen Van
Troi,
Ward 11, Phu Nhuan District,
Ho Chi Minh City, Vietnam
Tel : 08 38453222
Fax : 08 38455222
E-mail (Sales)
sales.emea@brtichip.com
E-mail (Sales)
sales.apac@brtchip.com
E-mail (Support)
support.emea@brtchip.com
E-mail (Support)
support.apac@brtchip.com
Web Site
http://brtchip.com/
Distributor and Sales Representatives
Please visit the Sales Network page of the Bridgetek Web site for the contact details of our distributor(s) and sales
representative(s) in your country.
System and equipment manufacturers and designers are responsible to ensure that their systems, and any Bridgetek Pte Ltd (BRT
Chip) devices incorporated in their systems, meet all applicable safety, regulatory and system-level performance requirements. All
application-related information in this document (including application descriptions, suggested Bridgetek devices and other materials) is
provided for reference only. While Bridgetek has taken care to assure it is accurate, this information is subject to customer
confirmation, and Bridgetek disclaims all liability for system designs and for any applications assistance provided by Bridgetek. Use of
Bridgetek devices in life support and/or safety applications is entirely at the user’s risk, and the user agrees to defend, indemnify and
hold harmless Bridgetek from any and all damages, claims, suits or expense resulting from such use. This document is subject to
change without notice. No freedom to use patents or other intellectual property rights is implied by the publication of this document.
Neither the whole nor any part of the information contained in, or the product described in this document, may be adapted or
reproduced in any material or electronic form without the prior written consent of the copyright holder. Bridgetek Pte Ltd, 178 Paya
Lebar Road, #07-03, Singapore 409030. Singapore Registered Company Number: 201542387H.
Copyright © Bridgetek Pte Ltd 59
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Appendix A – References
Document References
FT81x_Series_Programmer_Guide
AN_252 FT800 Audio Primer
AN_254 FT800 Designs with Visual TFT
AN_259 FT800 Example with 8-bit MCU
AN_275 FT800 Example with Arduino
AN_276 Audio File Conversion
AN_277 FT800 Create User Defined Font
AN_281 FT800 Emulator Library User Guide
AN_291 FT800 Create Multi-Language Font
AN_299 FT800 FT801 Internal Clock Trimming
AN_303 - FT800 Image File Conversion
AN_308 FT800 Example with an 8-bit MCU
AN_312 FT800 Example with ARM
AN_314 FT800 Advanced Techniques - Working with Bitmaps
AN_318 Arduino Library for FT800 Series
AN_320 FT800 Example with PIC
AN_327 EVE Screen Editor Installation Guide
AN_333 FT800 and FT801 Touch Capabilities
AN_336 FT800 - Selecting an LCD Display
FT800 Series Sample Application
EVE Frequently Asked Questions
Acronyms and Abbreviations
Terms
Description
ADPCM
Adaptive Differential Pulse Code Modulation
ASCII
American Standard Code for Information Interchange
EVE
Embedded Video Engine
HMI
Human Machine Interfaces
I2C
Inter-Integrated Circuit
LCD
Liquid Crystal Display
LED
Light Emitting Diode
MCU
Micro Controller Unit
MPU
Micro Processor Unit
Copyright © Bridgetek Pte Ltd 60
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
PCM
Pulse Code Modulation
PLL
Phased Locked Loop
PWM
Pulse Width Modulation
QVGA
Quarter Video Graphics Array
ROM
Read Only Memory
SPI
Serial Peripheral Interface
VQFN
Very Thin Quad Flat Non-Leaded Package
Copyright © Bridgetek Pte Ltd 61
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Appendix B - List of Figures and Tables
List of Figures
Figure 2-1 FT81x Block Diagram ..................................................................................................... 3
Figure 2-2 FT81x System Design Diagram ....................................................................................... 3
Figure 4-1 SPI master and slave in the master read case ................................................................. 14
Figure 4-2 Single/Dual SPI Interface connection ............................................................................. 14
Figure 4-3 Quad SPI Interface connection ...................................................................................... 15
Figure 4-4 Internal relaxation oscillator connection ......................................................................... 21
Figure 4-5 Crystal oscillator connection ......................................................................................... 21
Figure 4-6 External clock input ..................................................................................................... 21
Figure 4-7 RGB timing waveforms ................................................................................................. 29
Figure 4-8 Resistive Touch screen connection ................................................................................. 33
Figure 4-9 Touch screen connection .............................................................................................. 34
Figure 4-10 Internal regulator ...................................................................................................... 37
Figure 4-11 Power State Transition ............................................................................................... 38
Figure 6-1 SPI Interface Timing .................................................................................................... 50
Figure 6-2 RGB Interface Timing ................................................................................................... 52
Figure 7-1 FT812 application circuit............................................................................................... 53
Figure 7-2 FT813 application circuit............................................................................................... 53
Figure 7-3 Backlight drive circuit .................................................................................................. 54
Figure 7-4 Audio filter and amplifier circuit ..................................................................................... 54
Figure 8-1 VQFN-48 Package Dimensions ...................................................................................... 56
Figure 8-2 VQFN-56 Package Dimensions ...................................................................................... 56
Figure 8-3 FT81x Solder Reflow Profile .......................................................................................... 57
List of Tables
Table 3-1 FT81x pin description .................................................................................................... 12
Table 4-1 QSPI channel selection .................................................................................................. 13
Table 4-2 Host memory read transaction ....................................................................................... 15
Table 4-3 Host memory write transaction ...................................................................................... 16
Table 4-4 Host command transaction ............................................................................................ 16
Table 4-5 Host command list ........................................................................................................ 20
Table 4-6 Interrupt Flags bit assignment ....................................................................................... 20
Table 4-7 Font table format ......................................................................................................... 23
Table 4-8 ROM font table ............................................................................................................. 23
Table 4-9 ROM font ASCII character width in pixels ......................................................................... 26
Table 4-10 ROM font Extended ASCII characters ............................................................................ 26
Table 4-11 RGB PCLK frequency ................................................................................................... 27
Copyright © Bridgetek Pte Ltd 62
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Table 4-12 REG_SWIZZLE RGB Pins Mapping ................................................................................. 28
Table 4-13 Registers for RGB horizontal and vertical timings ............................................................ 28
Table 4-14 Output drive current selection ...................................................................................... 30
Table 4-15 Sound Effect .............................................................................................................. 31
Table 4-16 MIDI Note Effect ......................................................................................................... 32
Table 4-17 Resistive Touch Controller Operating Mode .................................................................... 33
Table 4-18 Capacitive Touch Controller Operating Mode .................................................................. 34
Table 4-19 Power supply ............................................................................................................. 36
Table 4-20 Pin Status .................................................................................................................. 40
Table 5-1 FT81x Memory Map ...................................................................................................... 41
Table 5-2 Overview of FT81x Registers .......................................................................................... 46
Table 6-1 Absolute Maximum Ratings ............................................................................................ 47
Table 6-2 ESD and Latch-Up Specifications .................................................................................... 47
Table 6-3 Operating Voltage and Current ....................................................................................... 48
Table 6-4 Digital I/O Pin Characteristics (VCCIO = +3.3V) ............................................................... 48
Table 6-5 Digital I/O Pin Characteristics (VCCIO = +2.5V) ............................................................... 49
Table 6-6 Digital I/O Pin Characteristics (VCCIO = +1.8V) ............................................................... 49
Table 6-7 Touch Sense Characteristics .......................................................................................... 49
Table 6-8 System clock characteristics .......................................................................................... 50
Table 6-9 SPI Interface Timing Specification .................................................................................. 51
Table 6-10 RGB interface timing characteristics .............................................................................. 51
Table 8-1 Reflow Profile Parameter Values ..................................................................................... 57
Copyright © Bridgetek Pte Ltd 63
FT81X Embedded Video Engine Datasheet
Version 1.4
Document No.: BRT_000002 Clearance No.: BRT#004
Appendix C - Revision History
Document Title: FT81X Embedded Video Engine Datasheet
Document Reference No.: BRT_000002
Clearance No.: BRT#004
Product Page: http://brtchip.com/product
Document Feedback: Send Feedback
Revision
Changes
Date
Draft
Initial Release
2015-02-15
1.0
Revised Release
2015-07-07
1.1
Revised Release
2015-09-14
1.2
Revised Release
2015-09-29
1.3
Dual branding to reflect the migration of the product
to the Bridgetek name – logo changed, copyright
changed, contact information changed
Updated table 4-10 ROM Font Extended ASCII
characters
2016-09-13
1.4
Document Migrated from Dual branding (FTDI/BRT)
to Bridgetek – Dual branding logo replaced with BRT
Logo
All document reference hyperlinks updated to point
BRT wesbite
Updated all the chip markings from FTDI to BRT
2017-06-30
