ISL76683 [RENESAS]
Light-to-Digital Output Sensor with Gain Selection, Interrupt Function and I2C Interface;型号: | ISL76683 |
厂家: | RENESAS TECHNOLOGY CORP |
描述: | Light-to-Digital Output Sensor with Gain Selection, Interrupt Function and I2C Interface |
文件: | 总18页 (文件大小:850K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
DATASHEET
ISL76683
FN7697
Rev 9.00
Mar 2, 2018
Light-to-Digital Output Sensor with Gain Selection, Interrupt Function and
2
I C Interface
The ISL76683 is an integrated light sensor with an internal
Features
integrating ADC intended for automotive applications. The ADC
provides 16-bit resolution and is capable of rejecting 50Hz and
2
• Range select with I C
2
60Hz flicker caused by artificial light sources. The I C interface
- Range 1 = 0 lux to 1000 lux
- Range 2 = 0 lux to 4000 lux
provides four user programmable lux sensitivity ranges for
optimized counts/lux in a variety of lighting conditions. The I C
2
- Range 3 = 0 lux to 16000 lux
- Range 4 = 0 lux to 64000 lux
interface also provides multi-function control of the sensor and
remote monitoring capabilities.
• Human eye response (540nm peak sensitivity)
• Temperature compensated
In normal operation, power consumption is less than 300µA.
Furthermore, a software power-down mode controlled with the
I C interface reduces power consumption to less than 1µA.
2
• 16-bit resolution
The ISL76683 supports twin (upper and lower) user
programmed thresholds and provides a hardware interrupt
that remains asserted low until the host clears it with the I C
control interface.
• Adjustable sensitivity: up to 65 counts per lux
• User-programmable upper and lower threshold interrupt
• Simple output code, directly proportional to lux
• IR + UV rejection
2
The ISL76683 is designed to operate on supplies from 2.5V to
3.3V, and is AEC-Q100 qualified and specified for operation
across the -40°C to +105°C (grade 2) ambient temperature
range. To achieve this, the ISL76683 is packaged in a special
extended temperature clear package.
• 50Hz/60Hz rejection
• 2.5V to 3.3V supply
• 6 Ld ODFN (2.1mmx2mm)
• AEC-Q100 qualified
Related Literature
For a full list of related documents, visit our website
• ISL76683 product page
• Pb-free (RoHS compliant)
Applications
• Automotive ambient light sensing
• Backlight control
• Lighting controls
VDD
1
PHOTODIODE 1
COMMAND
REGISTER
INTEGRATING
ADC
DATA
REGISTER
MUX
5
6
SCL
SDA
PHOTODIODE 2
IREF
2
I C
EXT
TIMING
FOSC
INT
16
2
INTERRUPT
4
INT
COUNTER
3
2
REXT
GND
ISL76683
FIGURE 1. BLOCK DIAGRAM
FN7697 Rev 9.00
Mar 2, 2018
Page 1 of 18
ISL76683
Pin Configuration
ISL76683
(6 LD ODFN)
TOP VIEW
VDD
GND
1
2
3
6
5
4
SDA
SCL
INT
THERMAL
PAD
REXT
Pin Descriptions
PIN NUMBER
PIN NAME
DESCRIPTION
1
2
3
4
5
6
VDD
Positive supply. Connect this pin to a regulated 2.5V to 3.3V supply
GND
Ground pin. The thermal pad is connected to the GND pin
REXT
INT
External resistor pin for ADC reference. Connect this pin to ground through a (nominal) 100k resistor
Interrupt pin; LO for interrupt/alarming. The INT pin is an open drain.
2
2
SCL
I C serial clock
The I C bus lines can be pulled above VDD, 5.5V max
2
SDA
I C serial data
Ordering Information
PART NUMBER
TEMP RANGE
(°C)
TAPE AND REEL
(UNITS)
PACKAGE
(RoHS Compliant)
PKG.
DWG. #
(Notes 1, 2, 3)
ISL76683AROZ-T7
ISL76683AROZ-T7A
-40 to +105
-40 to +105
3k
6 Ld ODFN
6 Ld ODFN
L6.2x2.1
L6.2x2.1
250
ISL76683EVAL1Z
NOTES:
Evaluation Board
1. Refer to TB347 for details about reel specifications.
2. These Pb-free plastic packaged products employ special Pb-free material sets; molding compounds/die attach materials and NiPdAu plate - e4 termination
finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Pb-free products are MSL classified at Pb-free peak reflow
temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020.
3. For Moisture Sensitivity Level (MSL), refer to the ISL76683 product information page. For more information about MSL, refer to TB477.
FN7697 Rev 9.00
Mar 2, 2018
Page 2 of 18
ISL76683
Absolute Maximum Ratings (T = +25°C)
Thermal Information
A
V
, Supply Voltage between VDD and GND . . . . . . . . . . . . . . . . . . . . .3.6V
Thermal Resistance (Typical)
6 Ld ODFN Package (Notes 4, 5) . . . . . . . .
Maximum Die Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .+105°C
Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-40°C to +105°C
Operating Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . .-40°C to +105°C
Pb-Free Reflow Profile (Note 6). . . . . . . . . . . . . . . . . . . . . . . . . . . see TB477
JA (°C/W)
88
JC (°C/W)
7.94
DD
2
I C Bus Pin Voltage (SCL, SDA). . . . . . . . . . . . . . . . . . . . . . . . . -0.2V to 5.5V
2
I C Bus Pin Current (SCL, SDA). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . <10mA
INT, R
ESD Rating
Pin Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.2V to V
EXT
DD
Human Body Model (Tested per AEC-Q100-002) . . . . . . . . . . . . . . . . 2kV
Machine Model (Tested per AEC-Q100-003). . . . . . . . . . . . . . . . . . 200V
Charge Device Model (Tested per AEC-Q100-011). . . . . . . . . . . . . . . 1kV
Latch-Up (Tested per AEC-Q100-004, Class II, Level A) . . . . . . . . . . 100mA
CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product
reliability and result in failures not covered by warranty.
NOTES:
4. is measured with in free air with the component mounted on a high-effective thermal conductivity test board with “direct attach” features. See
JA
TB379.
5. For , “case temperature” location is at the center of the exposed metal pad on the package underside. See TB379.
JC
6. Peak temperature during solder reflow +260°C max.
Electrical Specifications V = 3V, T = +25°C, R = 100kΩ 1% tolerance, unless otherwise specified, Internal Timing Mode Operation
DD
A
EXT
(see “Principles of Operation” on page 6).
MIN
MAX
PARAMETER
Power Supply Range
Supply Current
SYMBOL
TEST CONDITIONS
(Note 7)
TYP
(Note 7)
UNIT
V
V
2.25
3.3
0.33
1
DD
I
0.29
0.1
mA
DD
Supply Current Disabled
I
Software disabled, -40°C to +85°C
µA
DD1
Software disabled, -40°C to +105°C, V = 3.3V
DD
0.1
8
µA
Internal Oscillator Frequency
Internal Oscillator Frequency
f
f
Gain/Range = 1 or 2
Gain/Range = 3 or 4
290
580
1
327
655
360
720
400
5
kHz
OSC1
kHz
OSC2
2
2
I C Clock Rate
FI C
kHz
Diode1 Dark ADC Code
Full Scale ADC Code
DATA0
DATA1
DATA2
E = 0 lux, Mode1, Gain/Range = 1
Counts
Counts
Counts
65535
24440
Diode1 ADC Code Gain/Range = 1
Accuracy
Mode1
Mode2
Mode1
Mode2
Mode1
Mode2
Mode1
Mode2
E = 300 lux, fluorescent light,
Gain/Range = 1
(Note 8)
15760
20200
2020
5050
505
Diode2 ADC Code Gain/Range = 1
Accuracy
DATA3
DATA4
DATA5
DATA6
DATA5
DATA6
DATA6
Counts
Counts
Counts
Counts
Counts
Counts
Counts
Diode1 ADC Code Gain/Range = 2
Accuracy
E = 300 lux, fluorescent light,
Gain/Range = 2
(Note 8)
Diode2 ADC Code Gain/Range = 2
Accuracy
Diode1 ADC Code Gain/Range = 3
Accuracy
E = 300 lux, fluorescent light,
Gain/Range = 3
(Note 8)
1262
126
Diode2 ADC Code Gain/Range = 3
Accuracy
Diode1 ADC Code Gain/Range = 4
Accuracy
E = 300 lux, fluorescent light,
Gain/Range = 4
(Note 8)
316
Diode2 ADC Code Gain/Range = 4
Accuracy
32
Voltage of REXT Pin
V
-40°C to +85°C
-40°C to +105°C
(Note 9)
0.485
0.51
0.535
0.545
V
V
V
REF
SCL and SDA Threshold LO
V
1.05
TL
FN7697 Rev 9.00
Mar 2, 2018
Page 3 of 18
ISL76683
Electrical Specifications V = 3V, T = +25°C, R = 100kΩ 1% tolerance, unless otherwise specified, Internal Timing Mode Operation
DD
A
EXT
(see “Principles of Operation” on page 6). (Continued)
MIN
MAX
PARAMETER
SCL and SDA Threshold HI
SDA Current Sinking Capability
INT Current Sinking Capability
NOTES:
SYMBOL
TEST CONDITIONS
(Note 7)
TYP
1.95
5
(Note 7)
UNIT
V
V
(Note 9)
TH
I
3
3
mA
mA
SDA
I
5
INT
7. Compliance to datasheet limits is assured by one or more methods: production test, characterization, and/or design.
8. Fluorescent light is substituted by a white LED during production.
9. The voltage threshold levels of the SDA and SCL pins are V dependent: V = 0.35*V . V = 0.65*V
DD TL DD TH
.
DD
Typical Performance Curves (R = 100k)
EXT
100
90
RADIATION PATTERN
0º
80
10º
10º
ISL76683 D1
20º
20º
70
LUMINOSITY
30º
30º
ANGLE
60
50
40
40º
40º
50º
60º
50º
60º
30
20
10
0
ISL76683 D2
70º
80º
90º
70º
80º
90º
300
400
500
600
700
800
900
1k
0.2
0.4
0.6
0.8
1.0
WAVELENGTH (nm)
RELATIVE SENSITIVITY
FIGURE 2. SPECTRAL RESPONSE
FIGURE 3. RADIATION PATTERN
320
10
8
T
= +27°C
T = +27°C
A
COMMAND = 00H
0 lux
A
COMMAND = 00H
306
292
278
264
250
5000 lux
6
4
200 lux
RANGE 2
2
0
2.0
2.3
2.6
2.9
3.2
3.5
3.8
2.0
2.3
2.6
2.9
3.2
3.5
3.8
SUPPLY VOLTAGE (V)
SUPPLY VOLTAGE (V)
FIGURE 4. SUPPLY CURRENT vs SUPPLY VOLTAGE
FIGURE 5. OUTPUT CODE FOR 0 LUX vs SUPPLY VOLTAGE
FN7697 Rev 9.00
Mar 2, 2018
Page 4 of 18
ISL76683
Typical Performance Curves (R = 100k) (Continued)
EXT
1.015
1.010
1.005
1.000
0.995
0.990
320.0
319.5
319.0
318.5
318.0
T
= +27°C
T
= +27°C
A
A
COMMAND = 00H
5000 lux
200 lux
2.0
2.3
2.6
2.9
3.2
3.5
3.8
2.0
2.3
2.6
2.9
3.2
3.5
3.8
SUPPLY VOLTAGE (V)
SUPPLY VOLTAGE (V)
FIGURE 6. OUTPUT CODE vs SUPPLY VOLTAGE
FIGURE 7. OSCILLATOR FREQUENCY vs SUPPLY VOLTAGE
10
330
320
310
300
290
280
270
260
V
= 3V
DD
V
- 3V
DD
COMMAND = 00H
0 LUX
8
6
4
2
RANGE2
0
-60
-40
-20
0
20
40
60
80
100 120
-60
-40
-20
0
20
40
60
80
100 120
TEMPERATURE (°C)
TEMPERATURE (°C)
FIGURE 8. SUPPLY CURRENT vs TEMPERATURE
FIGURE 9. OUTPUT CODE FOR 0 LUX vs TEMPERATURE
330
1.10
V
= 3V
DD
V
= 3V
DD
1.08
1.06
1.04
1.02
1.00
0.98
0.96
0.94
0.92
COMMAND = 00H
329
328
327
326
325
5000 LUX
RANGE 3
200 LUX
RANGE 1
-60
-40
-20
0
20
40
60
80
100 120
-60
-40
-20
0
20
40
60
80
100 120
TEMPERATURE (°C)
TEMPERATURE (°C)
FIGURE 10. OUTPUT CODE vs TEMPERATURE
FIGURE 11. OSCILLATOR FREQUENCY vs TEMPERATURE
FN7697 Rev 9.00
Mar 2, 2018
Page 5 of 18
ISL76683
Interrupt Function
The active low interrupt pin is an open-drain pull-down
Principles of Operation
Photodiodes
The ISL76683 contains two photodiodes. Diode1 is sensitive to
both visible and infrared light, while Diode2 is sensitive mostly to
infrared light. The two diodes’ spectral responses are independent
from one another. See Figure 2 on page 4 in the “Typical
configuration. The interrupt pin serves as an alarm or monitoring
function to determine whether the ambient light exceeds the
upper threshold or the lower threshold. The user can also
configure the persistency of the interrupt pin. This eliminates any
false triggers, such as noise or sudden spikes in ambient light
conditions. For example, an unexpected camera flash can be
ignored by setting the persistency to eight integration cycles.
Performance Curves” section. The photodiodes convert light to
current, then the diodes’ current outputs are converted to digital by
a single built-in integrating type 16-bit Analog-to-Digital Converter
2
2
I C Interface
(ADC). An I C command mode determines which photodiode will
be converted to a digital signal. Mode1 is Diode1 only. Mode2 is
Diode2 only. Mode3 is a sequential Mode1 and Mode2 with an
internal subtract function (Diode1 - Diode2).
Eight 8-bit registers are available inside the ISL76683. The
command and control registers define the operation of the device.
The command and control registers do not change until the registers
are overwritten. Two 8-bit registers set the high and low interrupt
thresholds. There are four 8-bit data Read Only registers; two bytes
for the sensor reading and another two bytes for the timer counts.
The data registers contain the ADC's latest digital output and the
number of clock cycles in the previous integration period.
Analog-to-Digital Converter (ADC)
The converter is a charge-balancing integrating type 16-bit ADC.
The chosen method for conversion is best for converting small
current signals in the presence of AC periodic noise. For example,
a 100ms integration time highly rejects 50Hz and 60Hz power
line noise simultaneously. See “Integration Time or Conversion
Time” on page 11 and “Noise Rejection” on page 12.
2
The ISL76683’s I C interface slave address is hardwired
internally as 1000100. When 1000100x with x as R or W is sent
after the Start condition, this device compares the first seven bits
of this byte to its address and matches.
The built-in ADC offers the user flexibility in integration time or
conversion time. Two timing modes are available: Internal Timing
Mode and External Timing Mode. In Internal Timing Mode,
integration time is determined by an internal dual speed oscillator
Figure 12 on page 7 shows a sample one-byte read. Figure 13 on
page 7 shows a sample one-byte write. Figure 14 on page 7
shows a sync_iic timing diagram sample for externally controlled
(f
), and the n-bit (n = 4, 8, 12, 16) counter inside the ADC. In
2
OSC
integration time. The I C bus master always drives the SCL
External Timing Mode, integration time is determined by the time
(clock) line, while either the master or the slave can drive the
2
between two consecutive I C External Timing Mode commands. See
2
SDA (data) line. Figure 13 shows a sample write. Every I C
“External Timing Mode” on page 10. A good balancing act of
integration time and resolution depending on the application is
required for optimal results.
transaction begins with the master asserting a start condition
(SDA falling while SCL remains high). The following byte is driven
by the master and includes the slave address and read/write bit.
The receiving device is responsible for pulling SDA low during the
acknowledgment period.
2
The ADC has four I C programmable range selections to
dynamically accommodate various lighting conditions. The ADC
can be configured at its lowest range for very dim conditions. The
ADC can be configured at its highest range for very bright
conditions.
2
Every I C transaction ends with the master asserting a stop
condition (SDA rising while SCL remains high).
2
For more information about the I C standard, refer to the Philips
2
I C specification documents.
FN7697 Rev 9.00
Mar 2, 2018
Page 6 of 18
ISL76683
Start
DEVICE ADDRESS
A6 A5 A4 A3 A2 A1 A0
SDA DRIVEN BY MASTER
W
W
A
A
A
9
REGISTER ADDRESS
R7 R6 R5 R4 R3 R2 R1 R0
SDA DRIVEN BY MASTER
A
A
A
9
STOP
START
DEVICE ADDRESS
A6 A5 A4 A3 A2 A1 A0
SDA DRIVEN BY MASTER
A
A
A
9
DATA BYTE0
A
NAK
A
STOP
I2C DATA
I2C SDA
In
ISL76683
SDA DRIVEN BY
W
I2C SDA
Out
D7 D6 D5 D4 D3 D2 D1 D0
I2C CLK
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
9
2
FIGURE 12. I C READ TIMING DIAGRAM SAMPLE
Start
DEVICE ADDRESS
W
W
A
A
A
9
REGISTER ADDRESS
R7 R6 R5 R4 R3 R2 R1 R0
SDA DRIVEN BY MASTER
A
A
A
9
FUNCTIONS
A
A
A
9
STOP
I2C DATA
I2C SDA In
A6 A5 A4 A3 A2 A1 A0
SDA DRIVEN BY MASTER
B7 B6 B5 B4 B3 B2 B1 B0
I2C SDA Out
I2C CLK In
SDA DRIVEN BY MASTER
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
2
FIGURE 13. I C WRITE TIMING DIAGRAM SAMPLE
Start
DEVICE ADDRESS
A6 A5 A4 A3 A2 A1 A0
SDA DRIVEN BY MASTER
W
W
A
A
A
9
REGISTER ADDRESS
A Stop
I2C DATA
I2C SDA In
R7 R6 R5 R4 R3 R2 R1 R0
A
A
9
I2C SDA Out
SDA DRIVEN BY MASTER
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
I2C CLK In
2
FIGURE 14. I C sync_iic TIMING DIAGRAM SAMPLE
FN7697 Rev 9.00
Mar 2, 2018
Page 7 of 18
ISL76683
Register Set
Eight registers are available in the ISL76683. Table 1 summarizes the available registers and their functions.
TABLE 1. REGISTER SET
ADDR
(HEX)
REGISTER
NAME
BIT(S)
7
FUNCTION NAME
Enable
FUNCTIONS/DESCRIPTION
00
Command
0: Disable ADC-core
1: Enable ADC-core
6
5
ADCPD
0: Normal operation
1: Power-down Mode
Timing_Mode
0: Integration is internally timed
1: Integration is externally sync/controlled by I C host
2
4
Reserved
3:2
Mode<1:0>
Selects ADC work mode:
0: Diode1’s current to unsigned 16-bit data
1: Diode2’s current to unsigned 16-bit data
2: Difference between diodes (I1 - I2) to signed 15-bit data
3: Reserved
1:0
Width<1:0>
Number of clock cycles; n-bit resolution
16
0: 2 cycles
12
1: 2 cycles
8
2: 2 cycles
4
3: 2 cycles
01
Control
7
6
5
Ext_Mode
Test_Mode
Int_Flag
Always set to logic 0. Factory use only
Always set to logic 0
0: Interrupt is cleared or not yet triggered
1: Interrupt is triggered
4
Reserved
Always set to logic 0. Factory use only
3:2
Gain<1:0>
Selects the gain so the range is:
0: 0 to 1000 lux
1: 0 to 4000 lux
2: 0 to 16000 lux
3: 0 to 64000 lux
1:0
Int_Persist
<1:0>
Interrupt is triggered after:
0: 1 integration cycle
1: 4 integration cycles
2: 8 integration cycles
3: 16 integration cycles
02
03
04
05
06
07
Interrupt Threshold
HI
7:0
7:0
7:0
7:0
7:0
7:0
Interrupt Threshold High byte of HI interrupt threshold. Default is 0xFF
HI
Interrupt Threshold
LO
Interrupt Threshold High byte of the LO interrupt threshold. Default is 0x00
LO
LSB_Sensor
MSB_Sensor
LSB_Timer
MSB_Timer
LSB_Sensor
MSB_Sensor
LSB_Timer
MSB_Timer
Read-Only data register that contains the Least Significant Byte (LSB) of the
latest sensor reading
Read-Only data register that contains the Most Significant Byte (MSB) of the
latest sensor reading
Read-Only data register that contains the LSB of the timer counter value
corresponding to the latest sensor reading
Read-Only data register that contains the MSB of the timer counter value
corresponding to the latest sensor reading
FN7697 Rev 9.00
Mar 2, 2018
Page 8 of 18
ISL76683
4. Photodiode Select Mode; Bits 3 and 2. This function controls
the mux attached to the two photodiodes. In Mode1, the mux
directs the current of Diode1 to the ADC. In Mode2, the mux
directs the current of Diode2 only to the ADC. Mode3 is a
sequential Mode1 and Mode2 with an internal subtract
function (Diode1 - Diode2).
TABLE 2. WRITE ONLY REGISTERS
REGISTER
NAME
FUNCTIONS/
DESCRIPTION
ADDRESS
b1xxx_xxxx
sync_iic
clar_int
Writing a logic 1 to this address bit ends
the current ADC-integration and starts
another. Used with External Timing Mode
only
TABLE 6. PHOTODIODE SELECT MODE; BITS 2 AND 3
BITS 3:2
0:0
MODE
bx1xx_xxxx
Writing a logic 1 to this address bit clears
the interrupt
MODE1. ADC integrates or converts Diode1 only. Current
is converted to an n-bit unsigned data (Note 10)
0:1
1:0
1:1
MODE2. ADC integrates or coverts Diode2 only. Current is
converted to an n-bit unsigned data (Note 10)
Command Register 00(hex)
The Read/Write command register has five functions:
MODE3. A sequential MODE1 then MODE2 operation.
The difference current is an (n-1) signed data (Note 10)
1. Enable; Bit 7. This function either resets the ADC or enables
the ADC in normal operation. A logic 0 disables the ADC to
reset mode. A logic 1 enables the ADC to normal operation.
No Operation
NOTE:
TABLE 3. ENABLE
10. n = 4, 8, 12, or 16 depending on the number of clock cycles function.
BIT 7
OPERATION
5. Width; Bits 1 and 0. This function determines the number of
clock cycles per conversion. Changing the number of clock
cycles changes the resolution of the device and changes the
integration time, which is the period the device’s ADC
samples the photodiode current signal for a lux
measurement.
0
1
Disable ADC-Core to Reset-Mode (default)
Enable ADC-Core to Normal Operation
2. ADCPD; Bit 6. This function puts the device in a power-down
mode. A logic 0 puts the device in normal operation. A logic 1
powers down the device.
TABLE 7. WIDTH
TABLE 4. ADCPD
BITS 1:0
0:0
NUMBER OF CLOCK CYCLES
= 65536
= 4096
16
12
8
BIT 6
OPERATION
Normal Operation (default)
Power-down
2
2
2
2
0
1
0:1
1:0
= 256
= 16
4
1:1
For proper shutdown operation, it is recommended to disable the
2
ADC first then disable the chip. First send the I C command with
2
Control Register 01(hex)
Bit 7 = 0, then send the I C command with Bit 6 = 1.
The Read/Write control register has three functions:
3. Timing Mode; Bit 5. This function determines whether the
integration time is done internally or externally. In Internal
Timing Mode, integration time is determined by an internal dual
1. Interrupt flag; Bit 5. This is the status bit of the interrupt. The
bit is set to logic high when the interrupt thresholds have been
triggered, and logic low when not yet triggered.
speed oscillator (f
), and the n-bit (n = 4, 8, 12, 16) counter
OSC
inside the ADC. In External Timing Mode, integration time is
determined by the time between two consecutive external-sync
sync_iic pulse commands.
TABLE 8. INTERRUPT FLAG
BIT 5
OPERATION
Interrupt is cleared or not triggered yet
Interrupt is triggered
TABLE 5. TIMING MODE
0
1
BIT 5
0
OPERATION
Internal Timing Mode. Integration time is internally
timed determined by f
clock cycles
, REXT, and the number of
OSC
1
External Timing Mode. Integration time is externally
timed by the I C host
2
FN7697 Rev 9.00
Mar 2, 2018
Page 9 of 18
ISL76683
2. Range/Gain; Bits 3 and 2. The Full Scale Range can be
and the timer counter value can be used to eliminate the
resulting noise.
adjusted by an external resistor R
adjusted with I C using the Gain/Range function.
and/or it can be
EXT
2
TABLE 11. DATA REGISTERS
Gain/Range has four possible values, Range(k) where k is 1
through 4. Table 9 lists the possible values of Range(k) and
ADDRESS
(hex)
04
CONTENTS
the resulting FSR for some typical value R
resistors.
EXT
Least-significant byte of most recent sensor reading.
Most-significant byte of most recent sensor reading.
TABLE 9. RANGE/GAIN TYPICAL FSR LUX RANGES
05
FSR LUX
FSR LUX
FSR LUX
06
Least-significant byte of timer counter value corresponding to
most recent sensor reading.
BITS
3:2
RANGE
(k)
RANGE at
RANGE at
RANGE at
k
1
2
3
4
R
= 100k
R
= 50k
R
= 500k
EXT
EXT
EXT
07
Most-significant byte of timer counter value corresponding to
most recent sensor reading.
0:0
0:1
1:0
1:1
973
973
1946
195
3892
3892
15,568
62,272
7784
778
3114
15,568
62,272
31,136
Calculating Lux
The ISL76683’s output codes, DATA, are directly proportional to lux.
124,544
12,454
(EQ. 1)
E = DATA
3. Interrupt persist; Bits 1 and 0. The interrupt pin and the
interrupt flag are triggered/set when the data sensor reading
is out of the interrupt threshold window after m consecutive
number of integration cycles. The interrupt persist bits
determine m.
The proportionality constant is determined by the Full Scale
Range, FSR, and the n-bit ADC, which is user defined in the
command register. The proportionality constant can also be
viewed as the resolution; the smallest lux measurement the
device can measure is .
TABLE 10. INTERRUPT PERSIST
FSR
------------
(EQ. 2)
=
BITS 1:0
0:0
NUMBER OF INTEGRATION CYCLES
n
2
1
4
Full Scale Range, FSR, is determined by the software
programmable Range/Gain, Range(k), in the command register
0:1
and an external scaling resistor R , which is referenced to
100kΩ.
EXT
1:0
8
1:1
16
(EQ. 3)
100k
-----------------
FSR = Rangek
R
EXT
Interrupt Threshold HI Register 02(hex)
The transfer function effectively for each timing mode becomes:
This register sets the HI threshold for the interrupt pin and the
interrupt flag. By default, the Interrupt threshold HI is FF(hex).
The 8-bit data written to the register represents the upper MSB of
a 16-bit value. The LSB is always 00(hex).
INTERNAL TIMING MODE
100k
-----------------
Rangek
(EQ. 4)
R
EXT
----------------------------------------------------
E =
DATA
DATA
n
2
Interrupt Threshold LO Register 03(hex)
EXTERNAL TIMING MODE
This register sets the LO threshold for the interrupt pin and the
interrupt flag. By default, the Interrupt threshold LO is 00(hex).
The 8-bit data written to the register represents the upper MSB of
a 16-bit value. The LSB is always 00(hex).
100k
-----------------
Rangek
(EQ. 5)
R
EXT
----------------------------------------------------
E =
COUNTER
n = 4, 8, 12, or 16. This is the number of clock cycles
programmed in the command register.
Sensor Data Register 04(hex) and 05(hex)
When the device is configured to output a 16-bit data, the LSB is
accessed at 04(hex), and the MSB can be accessed at 05(hex).
The sensor data register is refreshed after every integration cycle.
Range(k) is the user defined range in the Gain/Range bit in the
command register.
R
is an external scaling resistor hardwired to the REXT pin.
EXT
Timer Data Register 06(hex) and 07(hex)
DATA is the output sensor reading in number of counts available
at the data register.
Note that the timer counter value is only available when using the
External Timing Mode. The 06(hex) and 07(hex) are the LSB and
MSB, respectively, of a 16-bit timer counter value corresponding
to the most recent sensor reading. Each clock cycle increments
the counter. At the end of each integration period, the value of
n
2 represents the maximum number of counts possible in
Internal Timing Mode. For the External Timing Mode, the
maximum number of counts is stored in the data register named
COUNTER.
2
this counter is made available over the I C. This value can be
used to eliminate noise introduced by slight timing errors caused
by imprecise external timing. For example, microcontrollers often
cannot provide high-accuracy command-to-command timing,
COUNTER is the number increments accrued for between
integration time for External Timing Mode.
FN7697 Rev 9.00
Mar 2, 2018
Page 10 of 18
ISL76683
The automatic f
OSC
improvement of signal-to-noise ratio when detecting very low lux
signals.
adjustment feature allows significant
Gain/Range, Range (k)
The Gain/Range can be programmed in the control register to
give Range (k) determining the FSR. Note that Range(k) is not
the FSR (see Equation 3). Range(k) provides four constants
Integration Time or Conversion Time
depending on programmed k that will be scaled by R
(see
EXT
Integration time is the period during which the device’s ADC
samples the photodiode current signal for a lux measurement.
Integration time, in other words, is the time to complete the
conversion of analog photodiode current into a digital signal
(number of counts).
Table 9). Unlike R , Range(k) dynamically adjusts the FSR. This
EXT
function is especially useful for maintaining excellent resolution
when light conditions are varying drastically.
Number of Clock Cycles, n-bit ADC
The number of clock cycles determines “n” in the n-bit ADC; 2 clock
n
Integration time affects the measurement resolution. For better
resolution, use a longer integration time. For short and fast
conversions, use a shorter integration time.
cycles is a n-bit ADC. n is programmable in the command register in
the width function. Depending on the application, a good balance of
speed and resolution has to be considered when deciding for n. For
fast and quick measurement, choose the smallest n = 4. For
maximum resolution without regard of time, choose n = 16.
Table 12 compares the trade-off between integration time and
resolution. See Equations 10 and 11 for the relation between
integration time and n. See Equation 3 for the relation between n
and resolution.
The ISL76683 offers user flexibility in the integration time to
balance resolution, speed, and noise rejection. Integration time can
be set internally or externally and can be programmed in the
command register 00(hex) Bit 5.
INTEGRATION TIME IN INTERNAL TIMING MODE
This timing mode is programmed in the command register
00(hex) Bit 5. Most applications use this timing mode. When
TABLE 12. RESOLUTION AND INTEGRATION TIME SELECTION
using the Internal Timing Mode, f
and n-bits resolution
OSC
determine the integration time. t is a function of the number of
RANGE1
RANGE4
f
= 327kHz
f
= 655kHz
int
OSC
OSC
clock cycles and f
.
OSC
RESOLUTION
LUX/COUNT
RESOLUTION
(LUX/COUNT)
n
1
(EQ. 9)
n
16
12
8
t
(ms)
t
(ms)
----------
INT
INT
100
for Internal Timing Mode only
t
= 2
int
f
osc
200
0.01
0.24
3.90
62.5
1
12.8
0.8
6.4
0.4
16
n = 4, 8, 12, and 16. n is the number of bits of resolution.
n
250
4000
Therefore, 2 is the number of clock cycles. n can be programmed
at the command register 00(hex) bits 1 and 0.
4
0.05
0.025
NOTE: R
= 100kΩ
EXT
t
is dual time because f
is dual speed depending on the
OSC
int
Gain/Range bit. Integration time as a function of R
and n is:
EXT
External Scaling Resistor R
The ISL76683 uses an external resistor R
and f
to fix its internal
determines the
, a dual
R
n
EXT
EXT
osc
EXT
(EQ. 10)
----------------------------------------------
t
= 2
int1
327kHz 100k
oscillator frequency, f
. Consequently, R
OSC EXT
t
is the integration time when the device is configured for
Internal Timing Mode and Gain/Range is set to Range1 or
int1
f
, integration time, and the FSR of the device. f
OSC OSC
speed mode oscillator, is inversely proportional to R . For user
simplicity, the proportionality constant is referenced to fixed
constants 100kΩ and 655kHz:
EXT
Range2.
R
n
EXT
(EQ. 11)
----------------------------------------------
t
= 2
int2
655kHz 100k
(EQ. 6)
(EQ. 7)
1
2
100k
-- -----------------
655kHz
fosc1 =
fosc2 =
R
EXT
t
is the integration time when the device is configured for
Internal Timing Mode and Gain/Range is set to Range3 or
Range4.
int2
100k
-----------------
655kHz
R
EXT
f
1 is the oscillator frequency when Range1 or Range2 are
OSC
set. This is nominally 327kHz when R
is 100kΩ.
EXT
f
2 is the oscillator frequency when Range3 or Range4 are
OSC
set. This is nominally 655kHz when R
is 100kΩ.
EXT
When the Range/Gain bits are set to Range1 or Range2, f
OSC
runs at half speed compared to when Range/Gain bits are set to
Range3 and Range4.
(EQ. 8)
1
2
--
1 = f
f
2
OSC
OSC
FN7697 Rev 9.00
Mar 2, 2018
Page 11 of 18
ISL76683
TABLE 13. INTEGRATION TIMES FOR TYPICAL R
EXT
VALUES (Note 11)
Noise Rejection
Integrating type ADCs generally have excellent noise-rejection
characteristics for periodic noise with frequencies that are an
integer multiple of the integration time. For instance, a 60Hz AC
RANGE1
RANGE2
RANGE3
RANGE4
R
(kΩ
EXT
n = 16-BIT
n = 12-BIT
6.4
n = 12-BIT
n = 4
0.013
0.025
unwanted signal’s sum from 0ms to k*16.66ms (k = 1, 2...k ) is
i
zero. Similarly, setting the device’s integration time to an integer
multiple of the periodic noise signal greatly improves the light
sensor output signal in the presence of noise.
50
100
200
3.2
6.5
100
(Note 12)
13
DESIGN EXAMPLE 1
200
500
400
26
64
13
32
0.050
0.125
The ISL76683 will be designed in a portable system. The
ambient light conditions that the device will be exposed to are at
most 500 lux, which is a good office lighting. The light source has
a 50/60Hz power line noise, which is not visible to the human
1000
NOTES:
11. Integration time in milliseconds.
12. Recommended R resistor value.
2
eye. The I C clock is 10kHz.
EXT
Solution 1 - Using Internal Timing Mode
INTEGRATION TIME IN EXTERNAL TIMING MODE
To achieve both 60Hz and 50Hz AC noise rejection, the
integration time must be adjusted to coincide with an integer
multiple of the AC noise cycle times.
(EQ. 14)
This timing mode is programmed in the command register
00(hex) Bit 5. External Timing Mode is recommended when
integration time can be synchronized to an external signal (such
as a PWM) to eliminate noise.
t
= i1 60Hz= j1 50Hz
int
For Mode1 or Mode2 operation, the integration starts when the
sync_iic command is sent over the I C lines. The device needs
two sync_iic commands to complete a photodiode conversion.
The integration then stops when another sync_iic command is
received. Writing a logic 1 to the sync_iic bit ends the current
ADC integration and starts another one.
The first instance of integer values at which t rejects both 60Hz
int
and 50Hz is when i = 6 and j = 5.
2
t
= 61 60Hz= 51 50Hz
= 100ms
int
int
(EQ. 15)
t
For Mode3, the operation is a sequential Mode1 and Mode2. The
device needs three sync_iic commands to complete two
photodiode measurements. The first sync_iic command starts the
conversion of the Diode1. The second sync_iic completes the
conversion of Diode1 and starts the conversion of Diode2. The
third sync_iic pulse ends the conversion of Diode2 and starts over
again to commence conversion of Diode1.
Next, determine the Gain/Range. Based on the application
condition given, lux(max) = 500 lux, a range of 1000 lux is
desirable. This corresponds to a Gain/Range Range1 mode.
Impose a resolution of n = 16-bit. Equation 10 determines R
.
EXT
t
327kHz 100k
int
------------------------------------------------------------
R
=
EXT
n
2
(EQ. 16)
The integration time, t , is determined by Equation 12:
int
R
= 50k
EXT
i 2
I
C
----------
t
=
(EQ. 12)
int
f 2
Note: For Internal Timing Mode and Gain/Range set to Range3 or
Range4 only.
I
C
2
2
i
f
is the number of I C clock cycles to obtain the t
I C
int.
Equation 3 determines the Full Scale Range, FSR:
2
2
is the I C operating frequency.
I C
100k
50k
-----------------
FSR = 1000 lux
(EQ. 17)
(EQ. 18)
The internal oscillator, f
, operates identically in both the
internal and external timing modes, with the same dependence
OSC
FSR = 2000 lux
on R . However, in External Timing Mode, the number of clock
EXT
n
cycles per integration is no longer fixed at 2 . The number of
The effective transfer function becomes:
clock cycles varies with the chosen integration time, and is
data
16
limited to 2 = 65536. To avoid erroneous lux readings, the
-------------
16
E =
2000 lux
2
integration time must be short enough to not allow an overflow in
the counter register.
65,535
-----------------
t
(EQ. 13)
when Range/Gain is set to Range1
when Range/Gain is set to Range3
int
f
OSC
f
= 327kHz*100kΩ/R
or Range2.
OSC
EXT
EXT
f
= 655kHz*100kΩ/R
OSC
or Range4.
FN7697 Rev 9.00
Mar 2, 2018
Page 12 of 18
ISL76683
TABLE 14. SOLUTION1 SUMMARY TO EXAMPLE DESIGN PROBLEM
IR Rejection
DESIGN PARAMETER
VALUE
100ms
All filament type light sources have a high presence of infrared
component invisible to the human eye. A white fluorescent lamp,
however, has a low IR content. As a result, output sensitivity may
vary depending on the light source. Maximum attenuation of IR
can be achieved by properly scaling the readings of Diode1 and
Diode2. Obtain data readings from sensor Diode1 (D1), which is
sensitive to visible and IR, then read from sensor Diode2 (D2),
which is mostly sensitive from IR. Equation 19 describes the
method of cancelling IR in Internal Timing mode.
t
int
R
50kΩ
EXT
Gain/Range Mode
FSR
Range1 = 1000 lux
2000 lux
16
2
Number of Clock Cycles
Transfer Function
DATA
----------------
(EQ. 19)
E =
2000 lux
D3 = nD1 – kD2
16
2
where:
Solution 2 - Using External Timing Mode
From Solution 1, the desired integration time is 100ms. Note
that the R resistor only determines the inter oscillator
Data = lux amount in number of counts less IR presence
D1 = data reading of Diode1
D2 = data reading of Diode2
EXT
frequency when using External Timing mode. Instead, the
integration time is the time between two sync_iic commands
sent through the I C. The programmer determines how many I C
clock cycles to wait between two external timing commands.
n = 1.85. This is a rounding factor to scale back the sensitivity to
ensure Equation 4 is valid.
2
2
k = 7.5. This is a scaling factor for the IR sensitive Diode2.
2
2
2
i
i
i
= f
t
= number of I C clock cycles
I C
I C* int
2
Flat Window Lens Design
A window lens will surely limit the viewing angle of the ISL76683.
The window lens should be placed directly on top of the device.
The thickness of the lens should be kept at minimum to
= 10kHz 100ms
*
I C
2
2
= 1,000 I C clock cycles. An external sync_iic command sent
I C
1000 cycles after another sync_iic command rejects both 60Hz
and 50Hz AC noise signals.
minimize loss of power due to reflection and also to minimize
loss of loss due to absorption of energy in the plastic material. A
thickness of t = 1mm is recommended for a window lens design.
The bigger the diameter of the window lens, the wider the
viewing angle is of the ISL76683. Table 16 on page 14 shows the
recommended dimensions of the optical window to ensure both
35° and 45° viewing angle. These dimensions are based on a
window lens thickness of 1.0mm and a refractive index of 1.59.
Next, pick an arbitrary R
EXT
Gain/Range Mode. For a maximum 500 lux, Range1 is
adequate. From Equation 3:
= 100kΩ and choose the
100k
100k
-----------------
FSR = 1000 lux
FSR = 1000 lux
The effective transfer function becomes:
WINDOW LENS
DATA
COUNTER
-------------------------------
E =
1000 lux
DATA is the sensor reading data located in data registers 04(hex)
and 05(hex)
t
D
TOTAL
D1
COUNTER is the timer counter value data located in data registers
06(hex) and 07(hex). In this sample problem, COUNTER = 1000.
TABLE 15. SOLUTION 2 SUMMARY TO EXAMPLE DESIGN PROBLEM
DESIGN PARAMETER
VALUE
100ms
ISL76683
D
LENS
t
int
= VIEWING ANGLE
R
100kΩ
EXT
FIGURE 15. FLAT WINDOW LENS
Gain/Range Mode
FSR
Range1 = 1000 lux
1000 lux
# of Clock Cycles
Transfer Function
COUNTER = 1000
DATA
-------------------------------
E =
1000 lux
COUNTER
FN7697 Rev 9.00
Mar 2, 2018
Page 13 of 18
ISL76683
TABLE 16. RECOMMENDED DIMENSIONS FOR A FLAT WINDOW
DESIGN
Window with Light Guide Design
If a smaller window is desired while maintaining a wide effective
viewing angle of the ISL76683, a cylindrical piece of transparent
plastic called the light guide or light pipe is needed to trap the
light and focus the light on to the device. The pipe should be
placed directly on top of the device with a distance of
D1 = 0.5mm to achieve peak performance. The light pipe should
have a minimum diameter of 1.5mm to ensure that whole area
of the sensor will be exposed (see Figure 16).
D
AT 35° VIEWING
ANGLE
D
AT 45° VIEWING
ANGLE
LENS
LENS
D
D1
TOTAL
1.5
0.50
1.00
1.50
2.00
2.50
2.25
3.00
3.75
4.30
5.00
3.75
4.75
5.75
6.75
7.75
2.0
2.5
3.0
3.5
t = 1
D1
Thickness of lens
Distance between ISL76683 and inner edge of lens
Diameter of lens
Distance constraint between the ISL76683 and lens
outer edge
D
D
LENS
TOTAL
NOTE: All dimensions are in mm.
D
LENS
LIGHT PIPE
D
>1.5mm
2
t
D
LENS
D
2
L
ISL76683
FIGURE 16. WINDOW WITH LIGHT GUIDE/PIPE
ꢀꢁꢆꢂPP
ꢂꢁꢀꢇPP
ꢆ
ꢀ
ꢈ
ꢇ
ꢀꢁꢂꢂPP
ꢂꢁꢀꢅPP
ꢂꢁꢇꢈPP
ꢉ
ꢊ
ꢂꢁꢀꢇPP
ꢂꢁꢄPP
FIGURE 17. SENSOR LOCATION DRAWING
FN7697 Rev 9.00
Mar 2, 2018
Page 14 of 18
ISL76683
Suggested PCB Footprint
Typical Circuit
Footprint pads should be a nominal 1-to-1 correspondence with
package pads. Because ambient light sensor devices do not
dissipate high power, heat dissipation through the exposed pad is
not important; instead, similar to DFN or QFN, the exposed pad
provides robustness in board mount process. Renesas
recommends mounting the exposed pad to the PCB, but this is
not mandatory.
A typical application for the ISL76683 is shown in Figure 18. The
2
ISL76683’s I C address is internally hardwired as 1000100. The
2
device can be tied onto a system’s I C bus together with other
2
I C compliant devices.
Soldering Considerations
Convection heating is recommended for reflow soldering; direct
infrared heating is not recommended. The plastic ODFN package
does not require a custom reflow soldering profile, and is
qualified to +260°C. A standard reflow soldering profile with a
+260°C maximum is recommended.
Layout Considerations
The ISL76683 is relatively insensitive to layout. Like other I C
devices, it is intended to provide excellent performance even in
significantly noisy environments. The following considerations
will ensure the best performance.
2
2
Route the supply and I C traces as far as possible from all
sources of noise. Use two power supply decoupling capacitors,
4.7µF and 0.1µF, placed close to the device.
1.8V TO 5.5V
2
I C MASTER
R1
R2
R3
10kΩ 10kΩ RES1
MICROCONTROLLER
SDA
SCL
2.5V TO 3.3V
2
2
2
I C SLAVE_1
I C SLAVE_0
I C SLAVE_n
1
2
6
5
4
SDA
SCL
SDA
SCL
VDD
SDA
SCL
INT
GND
REXT
C1
C2
3
4.7µF 0.1µF
R
EXT
ISL76683
100kΩ
FIGURE 18. ISL76683 TYPICAL CIRCUIT
FN7697 Rev 9.00
Mar 2, 2018
Page 15 of 18
ISL76683
Revision History
The revision history provided is for informational purposes only and is believed to be accurate, but not warranted. Please go to web to make sure you
have the latest revision.
DATE
REVISION
FN7697.9
CHANGE
Mar 2, 2018
Applied Renesas logo in header and footer.
Updated Related Literature section on page 1.
Updated Figure 17 on page 14.
Removed About Intersil section and added Renesas disclaimer.
Feb 26, 2016
FN7697.8
Removed sentence from “IR Rejection” on page 13, which referred to Figure 2.
Added Tape and Reel column to show units in “Ordering Information Table” on page 2.
Abs Max Ratings on page 3 - changed testing information from “Charge Device Model (Tested per
JESD22-C101C)” to “Charge Device Model (Tested per AEC-Q100-011)”. “Human Body Model (Tested per
JESD22-A114E)” to Human Body Model (Tested per AEC-Q100-002)”. “Machine Model (Tested per
JESD-A115-A)” to Machine Model (Tested per AEC-Q100-003). “Latch-up (Tested per JESD78B” to Latch-Up
(Tested per AEC-Q100-004, Class II, Level A).
Updated POD to most current revision. Revision POD change is as follows:
Changed Note 5 From: Tiebar shown (if present) is a non-functional feature.
To: Tiebar shown (if present) is a non-functional feature and maybe located on any of the 4 sides (or ends).
Mar 24, 2014
Dec 23, 2013
FN7697.7
FN7697.6
Added AEC-Q100 qualified to features on page 1.
Added Related Literature on page 1.
Added Eval board to ordering information on page 2.
Updated Figure 17 Sensor Location Drawing with Pin 1 Marking.
Page 16
- 2nd line of the disclaimer changed from:
"Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted"
to:
"Intersil Automotive Qualified products are manufactured, assembled and tested utilizing TS16949 quality
systems as noted"
Jul 22, 2013
Oct 30, 2012
FN7697.5
FN7697.4
Removed Confidential Watermark, Updated Product Information verbiage to About Intersil verbiage.
Added ISL76683AROZ-T7A to “Ordering Information” on page 2.
Updated “Package Outline Drawing” on page 17. Added "MAX 0.75" dimension to Side View.
Jul 9, 2012
FN7697.3
In “Control Register 01(hex)” on page 9, removed sentence: “Writing a logic low clears/resets the status bit.”
from “1. Interrupt flag; Bit 5”
Mar 8, 2011
Jan 24, 2011
FN7697.2
FN7697.1
Changed TechBrief reference in ordering information for MSL info from TB363 to TB477.
Initial Release to web.
FN7697 Rev 9.00
Mar 2, 2018
Page 16 of 18
ISL76683
For the most recent package outline drawing, see L6.2x2.1.
Package Outline Drawing
L6.2x2.1
6 LEAD OPTICAL DUAL FLAT NO-LEAD PLASTIC PACKAGE (ODFN)
Rev 4, 2/15
2.10
A
6
B
PIN #1
INDEX AREA
6
1
PIN 1
INDEX AREA
0.65
1.35 1.30 REF
2.00
4
6x0.30 ±0.05
(4X)
0.10
0.10 M C A B
0.65
6x0.35 ±0.05
TOP VIEW
BOTTOM VIEW
2.50
2.10
PACKAGE
OUTLINE
SEE DETAIL "X"
0.10 C
0.65
(4x0.65)
MAX 0.75
C
BASE PLANE
SEATING PLANE
0.08 C
SIDE VIEW
0.2 REF
(1.35)
5
C
(6x0.30)
(6x0.20)
(6x0.55)
TYPICAL RECOMMENDED LAND PATTERN
0.00 MIN.
0.05 MAX.
DETAIL "X"
NOTES:
1. Dimensions are in millimeters.
Dimensions in ( ) for Reference Only.
2. Dimensioning and tolerancing conform to ASME Y14.5m-1994.
3.
Unless otherwise specified, tolerance: Decimal ± 0.05
4. Dimension applies to the metallized terminal and is measured
between 0.15mm and 0.30mm from the terminal tip.
Tiebar shown (if present) is a non-functional feature and
maybe located on any of the 4 sides (or ends).
5.
6.
The configuration of the pin #1 identifier is optional, but must be
located within the zone indicated. The pin #1 identifier may be
either a mold or mark feature.
FN7697 Rev 9.00
Mar 2, 2018
Page 17 of 18
Notice
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