© Semiconductor Components Industries, LLC, 2013
November, 2013 Rev. 0
1Publication Order Number:
NCV7751/D
NCV7751
Twelve Low-Side Relay
Drivers
The NCV7751 is an automotive grade twelve channel lowside
driver providing drive capability up to 600 mA per channel. Output
control is via a SPI communication and offers convenient reporting of
faults for open load (or short to ground), over load, and over
temperature conditions. Additionally, all the drivers have integrated
output clamps for inductive loads.
The NCV7751 is available in a SSOP24 exposed pad package for
optimal thermal performance.
Features
12 Channels
600 mA LowSide Drivers
RDS(on) 1.3 W (typ), 2.5 W (max)
Configurable SPI Control (16/24/32 Bit)
Compatible with NCV7240
Frame Error Detection
Daisy Chain Capable
Power Up Without Open Circuit Detection Active (for LED
applications)
Low Quiescent Current in Sleep and Standby Modes
3.3 V and 5 V compatible Digital Input Supply Range
Fault Reporting
Open Load Detection (Selectable)
Over Load
Over Temperature
Poweron Reset (VDD, VDDA)
SSOP24 with an Exposed Pad
NCV Prefix for Automotive and Other Applications Requiring
Unique Site and Control Change Requirements; AECQ100
Qualified and PPAP Capable
These are PbFree Devices
Applications
Automotive Body Control Unit
Automotive Engine Control Unit
Relay Drive
LED Drive
Stepper Motor
SSOP24 NB EP
CASE 940AK
MARKING DIAGRAM
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Device Package Shipping
ORDERING INFORMATION
For information on tape and reel specifications,
including part orientation and tape sizes, please
refer to our Tape and Reel Packaging Specifications
Brochure, BRD8011/D.
NCV7751DQR2G SSOP24EP
(PbFree)
2500 /
Tape & Reel
NCV7751G
AWLYYWW
NCV7751 = Specific Device Code
A = Assembly Location
WL = Wafer Lot
YY = Year
WW = Work Week
G = PbFree Package
(Note: Microdot may be in either location)
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Low Side
Driver
Channel 112 OUT1
BIAS,
Supply Monitoring,
POR
SPI Input Logic Block
Fault
Reporting
Register
EN
VDDA
SI
SCLK
CSB1
GND GND GND GND
SO
VDD
Fault
Open Load
Over Load
Over Temperature
CSB2
OUT12
Control
Logic
OUT2
OUT10
OUT11
OUT9
OUT7
OUT8
OUT6
OUT5
OUT3
OUT4
VDD
Figure 1. Block Diagram
VDD
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PACKAGE PIN DESCRIPTION
SSOP24
EPAD Symbol Description
1 GND Ground.
2 GND Ground.
3 OUT1 Channel 1 lowside drive output. Requires an external pullup device for operation.
4 OUT2 Channel 2 lowside drive output. Requires an external pullup device for operation.
5 OUT3 Channel 3 lowside drive output. Requires an external pullup device for operation.
6 OUT4 Channel 4 lowside drive output. Requires an external pullup device for operation.
7 OUT5 Channel 5 lowside drive output. Requires an external pullup device for operation.
8 OUT6 Channel 6 lowside drive output. Requires an external pullup device for operation.
9 OUT7 Channel 7 lowside drive output. Requires an external pullup device for operation.
10 OUT8 Channel 8 lowside drive output. Requires an external pullup device for operation.
11 GND Ground.
12 GND Ground.
13 VDD Digital Power Supply for SO output (3.3 V or 5 V).
14 CSB2 Chip Select “Bar” Two (120 kW pull up resistor to VDD).
15 OUT9 Channel 9 lowside drive output. Requires an external pullup device for operation.
16 OUT10 Channel 10 lowside drive output. Requires an external pullup device for operation.
17 OUT11 Channel 11 lowside drive output. Requires an external pullup device for operation.
18 OUT12 Channel 12 lowside drive output. Requires an external pullup device for operation.
19 SO SPI serial data output. Output high voltage level referenced to pin VDD.
20 SCLK SPI clock (120 kW pull down resistor).
21 EN Global Enable (active high). (120 kW pull down resistor).
22 SI SPI serial data input (120 kW pull down resistor).
23 CSB1 SPI Chip Select “Bar” One (120 kW pull up resistor to VDD).
24 VDDA Analog Power Supply Input voltage (5 V).
EPAD Exposed Pad Connect to Ground or Leave Unconnected.
1
2
3
4
5
6
7
8
9
10
11
12
24
23
22
21
20
19
0.65 mm Pitch
GND
OUT1
GND
GND
GND
OUT2
OUT3
OUT4
OUT5
OUT6
OUT7
OUT8
VDD
OUT9
OUT11
OUT10
VDDA
CSB1
SCLK
SO
SI
EN
OUT12
18
17
16
15
14
13
CSB2
Figure 2. NCV7751 Pinout
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MAXIMUM RATINGS
Symbol Min Max Unit
Supply Input Voltage (VDDA, VDD)
DC VdcMax 0.3 5.5
V
Digital I/O pin voltage
(EN, CSB1, CSB2 SCLK, SI)
(SO)
VioMax 0.3
0.3
5.5
VDD + 0.3
V
High Voltage Pins (OUTx)
DC
Peak Transient
VoutxDcMax
VoutxAcMax
0.3 36
44**
V
Output Current (OUTx) 1 1.3 A
Clamping Energy
Maximum (single pulse)
Repetitive (multiple pulse)***
VclpDcMax
VclpAcMax
75
mJ
Operating Junction Temperature Range TJ40 150 °C
Storage Temperature Range Tstr 55 150 °C
ESD Capability, AECQ10002
Human body model (100 pF, 1.5 kW) (OUTx pins)
Human body model (100 pF, 1.5 kW) (all other pins)
Vesd4k
Vesd2k
4000
2000
4000
2000
V
ESD Capability, AECQ10003
Machine Model (200 pF)
Vesd200 200 200
V
AECQ10x12
Short Circuit Reliability Characterization
AECQ10x
Grade A
PACKAGE
Moisture Sensitivity Level MSL2 2
Lead Temperature Soldering: SMD style only, Reflow (Note 1)
PbFree Part 60 150 sec above 217°C, 40 sec max at peak
Treflow 265 peak °C
Package Thermal Resistance (Note 2)
SSOP24 EPAD
JunctiontoAmbient RqJA 57.9
°C/W
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality
should not be assumed, damage may occur and reliability may be affected.
**Internally limited. Specification applies to unpowered and powered modes. (0 V to VDDA, 0 V to VDD)
***2M pulses (triangular), VS = 15 V, 63 W, 390 mH, TA = 25°C. (See Figure 3)
1. For additional information, see or download ON Semiconductor’s Soldering and Mounting Techniques Reference Manual, SOLDERRM/D
and Application Note AND8083/D.
2. Values represent typical still air steadystate thermal performance on 2 oz. copper FR4 PCB with 645 mm2 copper area.
Figure 3. Repetitive Clamping Energy Test
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ELECTRICAL CHARACTERISTICS (3.0 V < VDD < VDDA, 4.5 V < VDDA (Note 3) < 5.5 V, 40°C v TJ v 150°C, EN = VDD
unless otherwise specified).
Characteristic Conditions Symbol Min Typ Max Unit
GENERAL
Operating Current (VDDA)
ON Mode
(All Channels On)
IopVDDA
3 5 mA
Quiescent Current (VDDA)
Global Standby Mode
(All Channels Off)
SI = SCLK = 0 V, CSB1 = CSB2 = VDD
40°C TJ 125°C
TJ = 150°C
IstbyVDDA125
IstbyVDDA150
32
40
mA
Quiescent Current (VDDA)
Low Iq Mode
SI = SCLK = EN = 0 V, CSB1 = CSB2 = VDD
40°C TJ 125°C
TJ = 150°C
IqVDDA125
IqVDDA150
10
20
mA
Operating Current (VDD)
ON Mode
(All Channels On)
EN = high, SCLK = 0 V,
CSB1 = CSB2 = VDD = VDDA
IopVDD 0.3 0.5 mA
Quiescent Current (VDD)
Global Standby Mode
(All Channels Off)
CSB1 = CSB2 = VDD = VDDA, fSCLK = 0 Hz
40°C TJ 125°C
TJ = 150°C
IstbyVDD125
IstbyVDD150
20
40
mA
Quiescent Current (VDD)
Low Iq Mode
EN = 0 V
40°C TJ 125°C
TJ = 150°C
IqVDD125
IqVDD150
5
20
mA
Total Quiescent Current
VDD + VDDA + OUTx
TJ = 125°C
OUTx = 18 V
EN = LHI = SCLK = SI = 0
VDDA = VDD = CSB1 = CSB2 = 5 V
Iqtot125 10 mA
Poweron Reset
threshold (VDDA)
VDDA rising
VDD = 3 V
VDDApor 3.8 4.5 V
Poweron Reset
Hysteresis (VDDA)
VDDAhys 250 mV
Poweron Reset
threshold (VDD)
VDD rising VDDpor 2.4 2.7 V
Poweron Reset
Hysteresis (VDD)
VDDAhys 165 mV
Thermal Shutdown
(Note 4)
Not ATE tested. Tsd 150 175 200 °C
Thermal Hysteresis Not ATE tested. TsHy 10 25 °C
OUTPUT DRIVER
Output Transistor RDS(on) IOUTx = 180 mA RDS(on)LS 1.3 2.5 W
Overload Detection
Current
Isd 0.6 0.95 1.3 A
Output Leakage OUTx = 13.5 V, 25°C
OUTx = 13.5 V
IsnkLkg25
IsnkLkg
1
5
mA
Output Clamp Voltage VDD = 0 V to 5.5 V
VDDA = 0 V to 5.5 V
IOUTx = 180 mA
Vclmp 36 40 44 V
Output Body Diode Voltage IOUTx = 180 mA VbdFwd 1.5 V
Open Load Detection
Threshold Voltage
Vol 1.0 1.75 2.5 V
Open Load Diagnostic
Sink Current
1 V < OUTx < 13.5 V, Output Disabled Iol 20 60 100 mA
3. Reduced performance down to 4 V provided VDDA is not in PowerOn Reset.
4. Each output driver is protected by its’ own individual thermal sensor.
5. Input signals HLH greater than 50usec are guaranteed to be detected.
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ELECTRICAL CHARACTERISTICS (3.0 V < VDD < VDDA, 4.5 V < VDDA (Note 3) < 5.5 V, 40°C v TJ v 150°C, EN = VDD
unless otherwise specified).
Characteristic UnitMaxTypMinSymbolConditions
OUTPUT TIMING SPECIFICATIONS
Enable (EN) wakeup time CSB1 = CSB2 = 0 V, VDDA = VDD = 5 V
EN going high 80% to SO active
TenWk 200 ms
Enable (EN) Valid Signal
Duration (Note 5)
VDDA = VDD = 5 V TenVld 50 ms
Serial Control Output
turnon time All Channels
VDS = 20% Vbat ,Vbat = 13.5 V, IDS = 180 mA
resistive load
ToutOn 15 50 ms
Serial Control Output
turnoff time All Channels
VDS = 80% Vbat,Vbat = 13.5 V, IDS = 180 mA
resistive load
ToutOff 12 50 ms
Over Load ShutDown
Delay Time
Tisd 3 15 50 ms
Open Load Detection Time Tol 30 115 200 ms
DIGITAL INTERFACE CHARACTERISTICS
Input Characteristics
Digital Input Threshold
(CSB1, CSB2, SI, SCLK,
EN)
VthIn 0.8 1.4 2.0 V
Digital Input Hysteresis
(CSB1, CSB2, SI, SCLK)
VhysIn 50 175 300 mV
Digital Input Hysteresis
(EN)
VthENHy 400 800 mV
Input Pulldown Resistance
(SI, SCLK, EN)
SI = SCLK = EN = VDD Rpdx 50 120 190 kW
Input Pullup Resistance
(CSB1, CSB2)
CSB1, CSB2 = 0 V RpdCSBx 50 120 190 kW
CSB1 and CSB2 Leakage
to VDD
CSB1 = CSB2 = 5 V, VDD = 0 V IlkgCSBVDD 100 mA
CSB1 and CSB2 Leakage
to VDDA
CSB1 = CSB2 = 5 V, VDDA = 0 V IlkgCSBVDDA 100 mA
Output Characteristics
SO Output High I(out) = 1.5 mA VsoH VDD
0.4
V
SO Output Low I(out) = 2.0 mA VsoL 0.6 V
SO Tristate Leakage CSB1 = CSB2 = VDD = 5.5 V ItriStLkg 3 0 3mA
3. Reduced performance down to 4 V provided VDDA is not in PowerOn Reset.
4. Each output driver is protected by its’ own individual thermal sensor.
5. Input signals HLH greater than 50usec are guaranteed to be detected.
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ELECTRICAL CHARACTERISTICS (3.0 V < VDD < VDDA, 4.5 V < VDDA (Note 3) < 5.5 V, 40°C v TJ v 150°C, EN = VDD
unless otherwise specified).
Characteristic UnitMaxTypMinSymbolConditions
DIGITAL INTERFACE CHARACTERISTICS
Timing (all timing specifications measured at 20% and 80% voltage levels)
SCLK Frequency Fclk 5 MHz
SCLK Clock Period TpClk 200 ns
SCLK High Time Figure 4 TclkH 85 ns
SCLK Low Time Figure 4 TclkL 85 ns
SI Setup Time Figure 4 TsiSup 50 ns
SI Hold Time Figure 4 TsiHld 50 ns
CSB1, CSB2 Setup Time Figure 4 TcsbxSup 100 ns
CSB1, CSB2 High Time
(Note 6)
Figure 4 TcsbH 1.5 ms
SCLK Setup Time Figure 4 TclkSup 85 ns
SO Output Enable Time
(CSB1, CSB2 falling to
SO valid)
Figure 4, Cload = 50 pF
VDDA = VDD = 5 V
TenSO 200 ns
SO Output Disable Time
(CSB1, CSB2 rising to
SO tristate)
Figure 4
VDDA = VDD = 5 V
TdisSO 200 ns
SO Output Data Valid
Time with capacitive load
Figure 4, Cload = 50 pF
VDDA = VDD = 5 V
TsoV 100 ns
6. Time between the trailing CSBx signal going high to complete a SPI cycle to the leading CSBx signal going low to start a new SPI cycle.
Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product
performance may not be indicated by the Electrical Characteristics if operated under different conditions.
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Figure 4. Detailed SPI Timing (measured at 20% and 80% voltage levels)
TclkH TclkL
TcsbxSup
TclkSup
TcsbH
TsoV
TclkSup
TcsbxSup
CSB1
CSB2
SO
TenSo TdisSO
SI
SCLK
SO
TsiSup
TsiHld
CSB2
CSB1
SCLK
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TYPICAL PERFORMANCE GRAPHS
Figure 5. VDD Low Iq Current vs. Temperature Figure 6. VDDA Low Iq Current vs. VDDA
TEMPERATURE (°C) VDDA (V)
14010080602002040
0.02
0
0.02
0.04
0.06
0.08
0.10
5.04.94.84.74.64.5
0
1
2
3
4
5
6
7
Figure 7. VDDA Low Iq Current vs.
Temperature
Figure 8. VDD Low Iq Quiescent Current
vs.VDD
TEMPERATURE (°C) VDDA (V)
12010080602002040
0
1
2
3
4
5
6
7
5.55.04.54.03.53.0
0.02
0
0.02
0.04
0.06
0.08
0.10
0.12
Figure 9. Output Clamping Voltage vs. Current Figure 10. Output Clamping Voltage vs.
Temperature
OUTPUT CURRENT (mA) TEMPERATURE (°C)
160130100704010
38.0
38.5
39.0
39.5
40.0
40.5
41.0
12010080402002040
39.5
40.0
40.5
41.0
41.5
42.0
42.5
VDD LOW Iq CURRENT (mA)
VDDA LOW Iq CURRENT (mA)
VDDA LOW Iq CURRENT (mA)
VDD LOW Iq CURRENT (mA)
OUTPUT VOLTAGE (V)
CLAMP VOLTAGE (V)
40 120
VDD = VDDA = 5 V
150°C
125°C
25°C
40°C
VDDA = VDD = 5 V
40 140
150°C
125°C
25°C
40°C
VDDA = 5 V
VDDA = 0 V
Tamb = 27°C
VDDA = 5.5 V
VDDA = 0 V
IOUTx = 180 mA
60 140
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TYPICAL PERFORMANCE GRAPHS
Figure 11. RDS(on) vs. Temperature Figure 12. Over Load Current vs. Temperature
TEMPERATURE (°C) TEMPERATURE (°C)
14010080602002040
0.5
1.0
1.5
2.0
2.5
3.0
14010080604002040
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.3
Figure 13. Open Load Detect Current vs.
Temperature
Figure 14. Output Leakage vs. Voltage
TEMPERATURE (°C) OUTPUT VOLTAGE (V)
12010080602002040
0
20
40
60
80
100
17.516.515.514.513.5
0
0.1
0.3
0.4
0.6
0.7
0.9
1.0
Figure 15. Output Leakage Current vs.
Temperature
Figure 16. Output Body Diode Voltage vs.
Temperature
TEMPERATURE (°C) TEMPERATURE (°C)
12010080602002040
0
0.1
0.3
0.4
0.6
0.7
0.9
1.0
12010080604002040
0
0.2
0.4
0.6
0.8
1.0
RDS(on) (W)
DETECTION CURRENT (A)
OPEN LOAD DETECTION CURRENT (mA)
OUTPUT CURRENT (mA)
OUTPUT CURRENT (mA)
BODY DIODE VOLTAGE (V)
40 120
680 mA
180 mA
20 120
40 140
0.2
0.5
0.8
TJ = 150°C
40 140
0.2
0.5
0.8
20 140
IOUTx = 180 mA
OUTx = 13.5 V
OUTx = 13.5 V
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TYPICAL PERFORMANCE GRAPHS
Figure 17. Open Load Detection Voltage vs.
Temperature
TEMPERATURE (°C)
1408060402002040
0
0.5
1.0
1.5
2.0
2.5
THRESHOLD VOLTAGE (V)
100 120
VDDA = 4.5 V, VDD = 3 V
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GENERAL OVERVIEW
The NCV7751 provides 12 independent 600 mA power
transistors with their source connection referenced to the
ground pin and with their drain connection brought out to
individual pins resulting in 12 independent lowside
drivers.
Internal clamping structures are provided to limit
transient voltages when switching inductive loads. Each
output has an over load detection current of 0.6 A (min)
where the driver will turnoff and stay latched off.
The NCV7751 has a dedicated Enable pin for low
quiescent mode operation. The different modes of operation
are summarized in Table 1, where the behavior of each mode
is a result of a programmed state via SPI, of an externally
triggered event (EN) or of the power supply requirements.
Table 1. MODES OF OPERATION
Modes of
Operation Conditions Description
UVLO Mode VDD or VDDA below their respective POR
thresholds
All outputs off in this mode.
Coming out of this mode
with EN = 1 sets all channels in the OFF mode
without open circuit diagnostic current enabled.
Low Iq Mode EN = low Provides a state with the lowest quiescent current for VDD
and VDDA.
OFF Mode SPI Control
(Command 11)
Output off.
Open circuit diagnosis current is disabled (powerup mode).
Open circuit diagnosis current is enabled (normal mode).
Global OFF Mode SPI Control
All Channels (Command 11)
Output off.
Open circuit diagnosis current is disabled (powerup mode).
Open circuit diagnosis current is enabled (normal mode).
ON Mode SPI Control
(Command 10)
Output on.
Standby Mode SPI Control
(Command 00)
Provides an OFF state with Open circuit diagnosis current
disabled.
All latched faults are cleared when Command 00 is sent.
Global
Standby Mode
SPI Control
All Channels (Command 00)
Provides a reduced quiescent current mode.
Provides an OFF state with
Open Load diagnostic current disabled.
The NCV7751 is available in a SSOP24 EPAD package.
Power up, PowerOn Reset (UVLO mode)
Both VDD and VDDA supply an independent
poweronreset function to the IC. Coming out of
poweronreset, all input bits are set to a 1 (OFF Mode) and
all output bits are set to a 0 except for the TER bit which is
set to a 1. The device cannot operate unless both supplies are
above their respective poweron reset thresholds. A breach
of VDD or VDDA PowerOn Reset thresholds will cause
the outputs to turn off and enter the UVLO mode.
The NCV7751 powers up into the Global OFF Mode
without the open circuit diagnostic current enabled and all
the faults registers cleared. In some application the
diagnostic current may be sufficient enough to produce a
noticeable illumination of the LED loads. The NCV7751
powerup behavior avoids unintentional illumination of the
LED loads when entering into Global Off Mode after
recovering from a POR condition. All other paths to Global
OFF Mode enable open circuit diagnostic current.
Enable Input (EN)
An Enable function (EN) provides a low quiescent sleep
current mode when the device is not being utilized. No data
is stored when the device is in sleep mode. An internal pull
down resistor is provided on the EN input to ensure the
device is off if the input signal is lost. Programming the EN
signal to a low state clears all the registers and resets the
driver. The EN input pin is a logic controlled input with a
voltage threshold defined by the VthIn parameter. When the
EN signal is asserted the IC will proceed with the VDDA
POR cycle and brings the drivers will enter into normal
operation (Global OFF Mode).
Serial Peripheral Interface (SPI) Communication
Serial Peripheral Interface (SPI) is used to establish a
communication medium between the master device and the
NCV7751. The SPI input data is stored in the input registers
and the diagnostic data that the slave device transmits to the
master is stored in the output registers. The input register
translates the SPI input to driver control logic consequently
controlling the gate of the LS drivers and the output register
transmits the output fault bits and the frame detection
integrity. The input data registers are 32 bits wide and the
output data registers are 33 bits wide and are defined here
forth:
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1. Input Register: Input for IC mode state and output
driver state control.
2. Output Register: Provides diagnostic information
on the output driver condition and transmission
error condition of the previous SPI cycle.
Given the size of the data registers, a decoded SPI
interface is utilized to access the two data registers in the
NCV7751. The decoded SPI interface offers the flexibility
of accessing either the entire data registers (input and output
registers) at once or just partially programming the data
registers with a 16bit or 24bit frame. The input and output
registers are divided into ports and subports for the ease of
explaining the decoded SPI structure and the
implementation of the diagnostic data shifted out to the SO
pin. Partitioning of the data registers are shown in Figure 18.
31
MSB
23 16 15 7 0
SI_Port2A
Reserved
31
MSB
23 16 15 7 0
OUTPUT REGISTERS
INPUT REGISTERS
TER
Addresses Channels 9 12
SI_Port2B SI_Port1A
Addresses Channels 8 5 Addresses Channels 4 1
SI_Port1B
SO_Port2A
Reserved Addresses Channels 12 9
SO_Port2B SO_Port1A
Addresses Channels 8 5 Addresses Channels 4 1
SO_Port1B
SO_Port2 SO_Port1
SI_Port2 SI_Port1
Figure 18. Input and Output Register Port Assignment
The partitioned register data can be programmed or
accessed through five different decoded scheme and they are
defined in Table 2. The decoding scheme is comprised of
two chip select signals generated from the input pins, CSB1
and CSB2 and an internally generated bit “FLEN”. Using
two CSB pins allow the conventional 16bit SPI frame to be
expanded to a 24bit or 32bit frame and still maintain
uniformity with the 16bit legacy devices such as the
NCV7240.
Table 2. SPI DECODING
SPI Mode
Name
Decoding Selection Signals
Input Bit
Requirement Input Register Functionality
Output Register
Functionality
FLEN
(Note 7) CSB2 CSB1
CSB_00 x 0 0 32 Bits Programs SI_Port2 and
SI_Port1
Reads SO_Port2 and
SO_Port1
CSB_01_T 0 0 1 16 Bits Programs SI_Port2 Reads SO_Port2B and
SO_Port1A
CSB_01_E 1 0 1 24 Bits Programs SI_Port2B and
SI_Port1
Reads SO_Port2B and
SO_Port1
CSB_10 x 1 0 16 Bits Programs SI_Port1 SO_Port1
CSB_11 x 1 1 SPI Inactive
7. FLEN: Auto Frame Detection Scheme on CSB2
16bit frame on CSB2: Truncated SPI Frame ³ FLEN = ‘0’
24bit frame on CSB2: Extended SPI Frame ³ FLEN = ‘1’
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A visual representation of the decoded SPI scheme is
demonstrated in Figure 19.
31
MSB
LSB
23 16 15 7 0
31
MSB
LSB
23 16 15 7 0
OUTPUT REGISTERS
INPUT REGISTERS
TER
CSB_00
CSB_01_T
CSB_01_E
CSB_10
CSB_01_E
CSB_10
CSB_01_T
CSB_00
Program Channels 12 1
Read Diagnostic Data from Channels 12 1
Read Diagnostic Data from Channels 8 1
Read Diagnostic Data from Channels 12 5
Figure 19. SPI Decoding Structure and Register Configuration Scheme
Reserved + Programs Channels 12 9 Programs Channels 8 1
Reserved + Programs Channels 12 1
Reserved + Read Diagnostic Data Channels 12 1
16Bit SPI Control: CSB_10 and CSB_01_T
SI_Port1 and SO_Port1 governed by CSB_10 mode are
identical to the NCV7240 devices, which supports channels
18 operation modes and diagnostics. Thus when CSB1 is
pulled low, the SPI data is multiplexed to SI_Port1 and the
data shifted out are of SO_Port1. CSB2 appends the SPI
operation for channels 9 12 by storing the driver control
and diagnostic data to data registers 23 down to 8. Bringing
CSB2 low while keeping CSB1 high allows data transfer to
SI_Port2 and the data retrieved on the SO pin is of
SO_Port2B and SO_Port1A when a 16bit frame is
generated from the master (CSB_01_T).
24Bit SPI Control: CSB_01_E
The autoframe configuration of CSB2 offers control and
diagnostic of all the output drivers through a single CSB2
cycle when a 24bit frame is transmitted from the master
(CSB_01_E). The autoframe configuration on CSB2 is
realized by an internal storage bit “FLEN”, where the bit is
set when a modulo 16 bit counter extends to a modulo 24bit
count. The SPI modes represented by the status of the
“FLEN” bit are displayed in Table 2.
32Bit SPI Control: CSB_00
If both CSB1 and CSB2 signals (CSB_00) are pulled low,
Port1’s input and output registers are serially connected to
Port2’s input and output registers respectively; effectively
making a single 32bit SPI interface.
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CSB1
SCLK
SI SO
CSB2
Output On / Off Control
00 = Standby Mode
01 = Reserved Mode
10 = ON Mode
11 = OFF Mode
Command Open Load
Over Load or Over temperature
Fault Output
Register
Input Registers Output Registers
FLEN
SPI Mode
Frame
Detection
16bit / 24bit
Figure 20. Detailed SPI Register Overview
Transmission Error Bit Only valid from CSB1
or/and CSB2 going low to going high.
SI_Port2 + SI_Port1, SO_Port2, SO_Port1
SI_Port2, SO_Port2B + SO_Port1A
SI_Port2B + SI_Port1, SO_Port2B + SO_Port1
SI_Port1, SO_Port1
Inactive
‘x00’ = CSB_00
‘001’ = CSB_01_T
‘101’ = CSB_01_E
‘x10’ = CSB_10
‘x11’ = CSB_11
(SI_Port1A, SI_Port1B, SI_Port2A, SI_Port2B) (SI_Port1A, SI_Port1B, SI_Port2A, SI_Port2B)
SPI Frame Overview
Depending on the SPI port configuration, words
generated from the masters should be composed of 16, 24 or
32 bits MSB (most significant bit) transmitted first.
Figure 21 shows the two 16bit frames for the SPI interface
configured as dual ports with the global TER bit and
Figure 22 illustrates a single frame consists of two words
and the TER bit.
B8B9B22
B23
CSB2
SI
SCLK
SO
MSB
B31 B30 B17 LSB
B16
TER
CSB1
MSB
B15 B14 B1 LSB
B0
B29 – B18 B13 – B2
B0B1B14
B15
TER
B21 – B10 B13 B2
Figure 21. SPI Interface Configured for SPI Mode: CSB_01_T then CSB_10
B0B1B30
B31
CSB1
CSB2
SI
SCLK
SO
MSB
B31 B30 B1 LSB
B0
TER
B29 B2
B29 B2 B0B1B22
B23
CSB2
SI
SCLK
SO
MSB
B23 B22 B1 LSB
B0
TER
B21 – B2
B21 – B2
Figure 22. SPI Interface Configured as SPI Mode:
CSB_00
Figure 23. SPI Interface Configured SPI Mode:
CSB_01_E
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Figure 23 shows the 24bit format for maximum
transmission efficiency when controlling 12 channels.
The following constraints must be met to assure proper SPI
communication:
1. CSB1 and/or CSB2 transition to the desired
decoded state to initiate SPI communication.
2. SCLK should be in a low state before CSB1 and/or
CSB2 transition from high to low.
3. CSB setup time (TcsbxSup) must be met from the
trailing CSBx signal to the first rising edge of
SCLK to allow decoding of the CSB signals.
4. Once the NCV7751 is decoded to the programmed
SPI mode, either zero SCLK pulse or the
minimum bit requirement must be met before any
transition of CSB1 and/or CSB2 signals to avoid a
transmission error (TER).
5. The MSB (most significant bit) is the first
transmitted bit.
6. Data is sampled from SI on the falling edge of
SCLK
7. Data is shifted out from SO on the rising edge of
SCLK
8. Once the required number of bits is shifted in, the
SCLK should idle low for a minimum of
TcsbxSup period before bring the CSB1 and/or
CSB2 signals high to complete the SPI cycle.
SI SPI Input Data (Serial structure of input word)
The data shifted into the input data registers are decoded
into instructions for each channel per the table below.
Standby Mode, ON Mode, and OFF Mode are all selectable
via the SPI for each channel independently.
The CSB mode required to access the different registers
are also provided in Table 3.
After a poweron reset, all register bits are set to a 1.
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Table 3. SPI INPUT DATA
Reserved
Channel 12
Channel 11
Channel 10
Channel 9
Channel 8
Channel 7
Channel 6
Channel 5
Channel 4
Channel 3
Channel 2
Channel 1
3124
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
MSB B31 SI_Port2 + SI_Port1 CSB_00 LSB B0
MSB B23 SI_Port2B + SI_Port1 CSB_01_E LSB B0
MSBB31 SI_Port2CSB_01_T LSBB16
MSB B15 SI_Port1 CSB_10 LSB B0
Input Data Register
Field Bits
Description
Reserved 3124 Reserved
channel x
(x=112)
23,22
21,20
19,18
17,16
15,14
13,12
11,10
9, 8
7,6
5,4
3,2
1,0
Command
00 Channel Standby Mode
Fast channel turn off
Fault Registers reset
Diagnostic Current Disabled
01 Reserved Mode
Channel turned off.
Diagnostic Current Enabled (Disabled after POR)
(Note 8)
10 ON Mode
Channel turned on.
Diagnostic Current Disabled
11 OFF Mode
Channel turned off.
Diagnostic Current Enabled (Disabled after POR)
(Note 8)
8. For Proper LED Operation
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SO Fault Diagnostic Retrieval (16 bit serial structure of
output word)
The decoded CSB mode and the frame length dictate the
output fault diagnostics appeared on the SO pin. Only output
fault diagnostics and frame detection errors are available
through the serial output (SO). The response frame (SO)
provides channelspecific (2 bits / channel) status
information fault reporting.
Table 4. SO DIAGNOSTIC DATA
CSB Mode Bit Requirement SO Reporting
CSB_00 32 Diagnostic data from output registers 31 0
CSB_01_E 24 Diagnostic data from output registers 23 0
CSB_01_T 16 Diagnostic data from output registers 23 8
CSB_10 16 Diagnostic data from output registers 15 0
CSB_11 Tristate
TER*
Reserved
TER*
Channel 12
Channel 11
Channel 10
Channel 9
TER*
Channel 8
Channel 7
Channel 6
Channel 5
Channel 4
Channel 3
Channel 2
Channel 1
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
P31
3124
P23
23
22
21
20
19
18
17
16
P15
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
MSB B31 SO_Port2 + SO_Port1 CSB_00 LSB B0
MSB B23 SO_Port2B + SO_Port1 CSB_01_E LSB B0
MSB B23 SO_Port2B + SO_Port1A CSB_01_T LSB B8
MSB B15 SO_Port1 CSB_10 LSB B0
Fault Diagnostic Register
Field Bits Description
TER CSB1 or CSB2
hightolow
Transmission Error.
0 Successful transmission in previous communication.
1 Frame detection error in previous transmission, exiting Limp Home or
exiting UVLO Mode.
Oln (n = 112) 1, 3, 5, 7, 9, 11, 13, 15,
17, 19, 21, 23
Open Load
0 Normal Operation
1 Fault detected
Dn (n = 112) 0, 2, 4, 6, 8, 10, 12, 14,
16, 18, 20, 22
Over Load or Over Temperature
0 Normal Operation
1 Fault detected
*TER Bit is available only when either or both CSB signals goes low and before the first SCLK rising edge
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Frame Detection
The NCV7751 detects the number of bits transmitted after
either CSB1 or CSB2 goes low. The device have minimum
bit requirement for the internal counter to insure that proper
number of bits are clocked in during the SPI cycle. After the
minimum bit count has been met, any multiple of 8bits are
allowed (minimum bit count + 8 * n). When the SPI ports are
configured separately, a minimum of 16 bits are needed to
avoid a frame error. Similarly, a minimum of 32 bits are
required when the SPI is configured as a single port by using
both CSB1 and CSB2 pins (CSB_00).
For data transferred via CSB2, 16bits are acceptable, but
a total of 24bits of data are required to fill the input
registers. Thus, it is crucial that if daisy chaining via CSB2
only, 24bits of data must be allocated for NCV7751.
The frame counter is enabled when either of the CSB
signals goes low and at the rising edge of the SCLK. By
default the frame detection counter is set to expire when it
exceeds 16 for the initial 16 clock cycles for CSB1 and
CSB2 and then a modulo eight counter is utilized. If both
CSB1 and CSB2 are low the counter immediately extends
the count to 32. Once the counter is extended to 32, it can
only be disabled once both CSB pulses are set high again.
Given that the bits clocked in didn’t violate the internal
frame detection counter, the data is latched into the input
register.
Transmission Error Reporting (TER)
Reporting of the TER bit in SO is treated as a global fault,
so any transmission error on either port or frame count is
reflected on the next CSB1 or CSB2 cycle. The TER is
cleared by sending a valid SPI command.
The transmission error information is available on SO
after either of the CSB signals goes low until the first rising
SCLK edge.
In addition to unqualified bit counts setting TER = 1, the bit
will also be set by
1. Coming out of UVLO.
2. Transitioning from Low Iq Mode to Global Off
Mode.
The TER bit is multiplexed with the SPI SO data and OR’d
with the SI input (Figure 24) to allow for reporting in a serial
daisy chain configuration. A TER error bit as a “1”
automatically propagates through the serial daisy chain
circuitry from the SO output of one device to the SI input of
the next. This is shown in Figures 25 and 26 first as the daisy
chained devices connected with no Transmission Error
(Figure 25) and subsequently with a Transmission Error in
device 1 propagating through to device 2 (Figure 26).
SI
TER
SPI
SI SO
S
SO
Figure 24. TER SPI Link
SI
TER
SO
NCV7751
SI
TER
SO
NCV7751
“0
‘‘0”
“0
“0
“0
Device #1
Device #2
Figure 25. TER (no error)
TER
SO
NCV7751
SI
TER
SO
NCV7751
“1
“1
“0
“1
Device #1
Device #2
Figure 26. TER Error Propagation
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Note TER is valid from CSB1 and/or CSB2 going low until
the 1st lowtohigh transition of SCLK to allow for
propagation of the SI signal (Reference Figures 21, 22
and 23).
TER Information Retrieval
TER information retrieval is as simple as bringing either
CSB1 or CSB2 hightolow. No clock signals are required.
Daisy Chain Setup
Daisy chain setups are possible with the NCV7751. The
serial setup shown in Figure 27 highlight two daisy chaining
configuration with the NCV7751:
1. Either tying (switch closed in Figure 27) or
stimulating the CSB1 and CSB2 signals together
2. With only CSB2 pin (switch open in Figure 27)
With these two different configurations, the number of
bits dedicated for NCV7751 is 24bits and 32bits for
option 1 and 2 respectively. Any other 16 bit device on the
chain is required to be using a similar SPI protocol.
Particular attention should be focused on the fact that the
initial data that are shifted out of the device are the
diagnostic information. The master must generate enough
input bits to propagate all the diagnostic bits from the slave
devices in the serial chain to the masters MISO registers.
The timing diagram shows a typical transfer of data from the
microprocessor to the SPI connected IC’s.
IC4
NCV7751
CSB2 SCLK
SI SO
IC3
CSB SCLK
SI SO
IC2
CSB SCLK
SI SO
Any IC
using 16 Bit
SPI
protocol
CSB SCLK
SI SO
microprocessor
IC1
Any IC
using16 Bit
SPI
protocol
Any IC
using16 Bit
SPI
protocol
CSB1
Bit Requirement for IC4
Close: 32BIts
Open: 24Bits
Figure 27. Serial Daisy Chain
CSB1
CSB2
SCLK
SI
1
st CMD 2nd CMD 3rd CMD 4th CMD
Figure 28. Serial Daisy Chain Timing Diagram with CSB1 tied to CSB2 (Switch Closed)
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Table 5. SERIAL DAISY CHAIN DATA PATTERN FOR CSB1 TIED TO CSB2 CONFIGURATION (SWITCH CLOSED)
CLK = 16 bits CLK = 32 bits CLK = 48 bits CLK = 64 bits CLK = 80 bits
IC4 1st CMD 2nd CMD 3rd CMD First Half of 4th CMD Second Half of 4th
CMD
IC3 IC4 DIAG SO_Port2 IC4 DIAG SO_Port1 1st CMD 2nd CMD 3rd CMD
IC2 IC3 DIAG IC4 DIAG SO_Port2 IC4 DIAG SO_Port1 1st CMD 2nd CMD
IC1 IC2 DIAG IC3 DIAG IC4 DIAG SO_Port2 IC4 DIAG SO_Port1 1st CMD
micro IC1 DIAG IC2 DIAG IC3 DIAG IC4 DIAG SO_Port2 IC4 DIAG SO_Port1
Table 5 refers to the progression of data over time of the
Serial Daisy Chain setup of Figure 27 with the switch closed
as word bits are shifted through the system. 80 bits are
needed for complete transport of data in the example system.
Each column of the table displays the status after transmittal
of each word (in 16 bit increments) and the location of each
word packet along the way.
The NCV7751 is also compatible with 8 bits devices due
to the features of the frame detection circuitry. The internal
bit counter of the NCV7751 starts counting clock pulses
when either or both CSB signals go low. After the minimum
bit requirement is met for the NCV7751, the subsequent
words can be comprised of just 8bits.
IC2
NCV7751
CSB2 SCLK
SI SO
IC1
CSB SCLK
SI SO
microprocessor
Any IC
using 8Bit
SPI
protocol
The NCV7751
is also
compatible with
8bit devices
CSB1
Compatibility
Note the SCLK timing requirements of the NCV7751.
Data is sampled from SI on the falling edge of SCLK.
Data is shifted out of SO on the rising edge of SCLK.
Devices with similar characteristics are required for
operation in a daisy chain setup.
Bit Requirement for IC2
Switch Close: 32Bits
Switch Open: 24Bits
Figure 29. Daisy Chaining with 8bit Devices
Output Drive Clamping
Internal zener diodes (Z1 and Z2, Figure 30) help to
protect the output drive transistors from the expected fly
back energy generated from an inductive load turning off.
Z1 provides the voltage setting of the clamp (along with Vgs
of the output transistor and Z2) while Z2 isolates Z1 from
normal turnon activity.
The output clamp voltage is specified between 36 V and
44 V. This includes clamping operation during unpowered
input supplies (VDD and VDDA). Device protection will be
provided when the load is driven from an alternative driver
source. This is an important feature when considering
protecting for load dump with an unpowered IC.
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Vdrain =VZ 1+VZ 2+ Vgs
Z1
Z2
g
s
drain
Vbat
GND
VDD
VDDA
OUTx
VBAT
VClamp = 36V (min) to 44V (max) Powered
GND
VDD
VDDA
OUTx
VBAT
Alternative
Driver
Source
VClamp = 36V (min) to 44V (max) Un
powered
Figure 30. Output Clamp
Over Temperature / Thermal Shutdown
The NCV7751 incorporates 12 individual thermal sensors
located in proximity to each output driver. A channel is
latched off upon the detection of an Over Temperature event.
This allows operation of unaffected channels before, during,
and after a channel detection of over temperature. The
thermal shutdown detection threshold is typically 175°C
with 25° of hysteresis.
Open Load Detection
Open Load Detection is achieved for each output with the
Open Load Detection Threshold Voltage reference voltage
(Vol) and its’ corresponding Open Load Diagnostic Sink
Current (when the output driver (OUTx) is off). The output
driver maintains its’ functionality with and without the open
bit set (i.e. it can turn on and off).
During normal operation, the open circuit impedance
(Roc) is zero ohms. This sets the voltage on OUTx to VS
volts. As long as VS is above Vol no open circuit fault will
be recognized. The voltage appearing on OUTx is a result of
VS and the voltage drop across Roc realized by the current
flow created by Iol.
The NCV7751 voltage level trip points are referenced to
ground. The threshold range is between 1.0 V and 2.5 V.
With a nominal battery voltage (VS) of 14 V, the resultant
worst case thresholds of detection are as follows.
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+
Open Load
detection
Channel x
GND
OUTx
Open
Load
Flag
1.75V
VS
Roc
60uA
Output
Turnon
Control
Vol
Iol
Vol = Open Load Detection Threshold Voltage
Iol = Open Load Diagnostic Sink Current
(VS *OpenLOadDetectionThresholdvoltage)
OpenLoadDiagnosticSinkCurrent +OpenLoadImpedance
ǒ14 *2.5 VǓ
100 mA+115 kWǒ14 V *1.0 VǓ
20 mA+650 kW
Open Load Detection is made when the
driver in OFF mode (command 11).
Figure 31. Open Load Detection
LED Loads
The NCV7751 features a power up feature for the Global
OFF Mode enabling the part to power up in a mode without
the open load diagnostic current enabled. This averts any
unintended illumination of LED loads during power up.
Over Current Protection
An Over Load Current ShutDown Delay Time of 3 ms
(min) is designed into the IC as a filter allowing for spikes
in current which may occur during normal operation and
allowing for protection from overload conditions.
Fault Handling
Registers are reset with the following conditions.
1. Channel in Standby Mode.
2. Poweron reset of VDD.
3. Poweron reset of VDDA.
4. EN low.
Table 6. FAULT SUMMARY
Output Fault Condition Fault Memory Miscellaneous
Open Load Latched Detected in Driver Off State (1.75 V (typ) threshold) when detection is enabled.
Reported in Output Fault Diagnostics Register until cleared via the SPI port.
Output will maintain turnon capability.
Over Load or Over Temperature Faults will be prioritized.
Short to Ground Latched Detection as part of the Open Load circuitry described above.
Short to Vbat N/A Protected via Over Load and Over Temperature functions.
Over Load Latched Detected in Driver On State
0.6 A (min), 1.3 (max)
A latched off condition must be cleared via the SPI port before it can be turned on.
Over Temperature Latched Detection in IC On State (TJ = 175°C (typ))
A latched off condition must be cleared via the SPI port before it can be turned on.
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PACKAGE DIMENSIONS
ÉÉÉ
ÉÉÉ
SSOP24 NB EP
CASE 940AK
ISSUE O
DIM MIN MAX
MILLIMETERS
A1.70
A1 0.00 0.10
L0.40 0.85
e0.65 BSC
c0.09 0.20
h0.25 0.50
b0.19 0.30
L2 0.25 BSC
M0 8
__
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME
Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETERS.
3. DIMENSION b DOES NOT INCLUDE DAMBAR
PROTRUSION. DAMBAR PROTRUSION SHALL
BE 0.10 MAX. AT MMC. DAMBAR CANNOT BE
LOCATED ON THE LOWER RADIUS OF THE
FOOT. DIMENSION b APPLIES TO THE FLAT
SECTION OF THE LEAD BETWEEN 0.10 TO 0.25
FROM THE LEAD TIP.
4. DIMENSION D DOES NOT INCLUDE MOLD
FLASH, PROTRUSIONS OR GATE BURRS. MOLD
FLASH, PROTRUSIONS OR GATE BURRS SHALL
NOT EXCEED 0.15 PER SIDE. DIMENSION D IS
DETERMINED AT DATUM PLANE H.
5. DIMENSION E1 DOES NOT INCLUDE INTERLEAD
FLASH OR PROTRUSION. INTERLEAD FLASH
OR PROTRUSION SHALL NOT EXCEED 0.25 PER
SIDE. DIMENSION E1 IS DETERMINED AT
DATUM PLANE H.
6. DATUMS A AND B ARE DETERMINED AT DATUM
PLANE H.
7. A1 IS DEFINED AS THE VERTICAL DISTANCE
FROM THE SEATING PLANE TO THE LOWEST
POINT ON THE PACKAGE BODY.
8. CONTOURS OF THE THERMAL PAD ARE UN-
CONTROLLED WITHIN THE REGION DEFINED
BY DIMENSIONS D2 AND E2.
PIN 1
REFERENCE
0.10
SEATING
PLANE
24X b
e
DETAIL A
---
SOLDERING FOOTPRINT
L
L2
GAUGE
DETAIL A
E1 3.90 BSC
PLANE
SEATING
PLANE
C
c
h
END VIEW
A-B
M
0.12 DC
TOP VIEW
SIDE VIEW
A-B0.20 C
112
24
A
B
D
2X 12 TIPS
A1
A2
C
C
24X
D8.64 BSC
E6.00 BSC
24X
1.15
24X
0.40 0.65
DIMENSIONS: MILLIMETERS
PITCH
6.40
1
2X
A
M
13
0.20 C
0.20 C
2X
0.10 C
RECOMMENDED
A2 1.651.10
EE1
D
NOTE 5
NOTE 6
NOTE 6
NOTE 4
A-B
M
0.15 DC
BOTTOM VIEW
E2
NOTE 8
D2
NOTE 8
A-B
M
0.15 DC
2.84
5.63
D2 5.28 5.58
E2 2.44 2.64
L1 1.00 REF
H
A1
NOTE 7
L1
h
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ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC owns the rights to a number of patents, trademarks,
copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/PatentMarking.pdf. SCILLC
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does not convey any license under its patent rights nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for
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