AVAGO ADJD-S313

ADJD-S313-QR999
Miniature Surface-Mount RGB Digital Color Sensor
Data Sheet
Description
Features
The ADJD-S313-QR999 is a cost effective, CMOS
digital output RGB color sensor in miniature
surface-mount package with a mere size of
5x5x0.75mm. The IC comes with integrated RGB
filters, an analog-to-digital converter and a digital
core for communication and sensitivity control. The
output allows direct interface to micro-controller
or other logic control for further signal processing
without the need of any additional components.
• Fully integrated RGB digital color sensor
This device is designed to cater for wide dynamic
range of illumination level and is ideal for
applications like portable or mobile devices which
demand higher integration, smaller size and low
power consumption. Sensitivity control is
performed by the serial interface and can be
optimized individually for the different color
channel. The sensor can also be used in conjunction
with a white LED for reflective color management.
• Built in internal oscillator
General Specifications
Feature
Value
• Digital I/O via 2-wire serial interface
• Industry’s smallest form factor – QFN 5x5x0.75mm
• Adjustable sensitivity for different levels of
illumination
• Uniformly distributed RGB photodiode array
• 7 bit resolution per channel output
• Sleep function when not in use
• No external components
• Low supply voltage (VDD) 2.6V
• 0°C to 70°C operating temperature
• Lead free package
Applications
• General color detection and measurement
Interface 100kHz serial interface
• Mobile appliances such as mobile phones, PDAs,
MP3 players,etc.
Supply
• Consumer appliances
2.6V digital (nominal), 2.6V analog (nominal)
• Portable medical equipments
• Portable color detector/reader
ESD WARNING: Standard CMOS handling precautions should be observed to avoid static discharge.
AVAGO TECHNOLOGIES' PRODUCTS AND SOFTWARE ARE NOT SPECIFICALLY DESIGNED, MANUFACTURED OR AUTHORIZED FOR SALE AS
PARTS, COMPONENTS OR ASSEMBLIES FOR THE PLANNING, CONSTRUCTION, MAINTENANCE OR DIRECT OPERATION OF A NUCLEAR FACILITY
OR FOR USE IN MEDICAL DEVICES OR APPLICATIONS. CUSTOMER IS SOLELY RESPONSIBLE, AND WAIVES ALL RIGHTS TO MAKE CLAIMS
AGAINST AVAGO TECHNOLOGIES OR ITS SUPPLIERS, FOR ALL LOSS, DAMAGE, EXPENSE OR LIABILITY IN CONNECTION WITH SUCH USE.
Powering the Device
No voltage must be applied to IO's during
power-up and power-down ramp time
VDDD / VDDA
0V
tVDD_RAMP
ESD Protection Diode Turn-On During Power-Up and
Power-Down
A particular power-up and power-down sequence must
be used to prevent any ESD diode from turning on
inadvertently. The figure above describes the sequence.
In general, AVDD and DVDD should power-up and
powerdown together to prevent ESD diodes from
turning on inadvertently. During this period, no voltage
should be applied to the IO’s for the same reason.
Ground Connection
AGND and DGND must both be set to 0V and preferably
star-connected to a central power source as shown in
the application diagram. A potential difference between
AGND and DGND may cause the ESD diodes to turn on
inadvertently.
Block Diagram
SDASLV
SCLSLV
XRST
Control
Core
Gain
Selection
RGB
PHOTOSENSOR
ARRAY
SLEEP
PHOTOCURRENT
TO VOLTAGE
CONVERSION
RED
ANALOG TO
DIGITAL
CONVERSION
2
PHOTOCURRENT
TO VOLTAGE
CONVERSION
GREEN
PHOTOCURRENT
TO VOLTAGE
CONVERSION
BLUE
Electrical Specifications
Absolute Maximum Ratings (Notes 1 & 2)
Parameter
Symbol
Minimum
Maximum
Units
Storage temperature
TSTG_ABS
-40
85
°C
Digital supply voltage, DVDD to DVSS
VDDD_ABS
-0.5
3.7
V
Analog supply voltage, AVDD to AVSS
VDDA_ABS
-0.5
3.7
V
Input voltage
VIN_ABS
-0.5
VDDD+0.5
V
Solder Reflow Peak temperature
TL_ABS
235
°C
Human Body Model ESD rating
ESDHBM_ABS
2
kV
Notes
All I/O pins
All pins, human
body model per
JESD22-A114-B
Recommended Operating Conditions
Parameter
Symbol
Minimum
Typical
Maximum
Units
Free air operating temperature
TA
0
25
70
°C
Digital supply voltage, DVDD to DVSS
VDDD
2.5
2.6
3.6
V
Analog supply voltage, AVDD to AVSS
VDDA
2.5
2.6
3.6
V
Output current load high
IOH
3
mA
Output current load low
IOL
3
mA
Input voltage high level (Note 4)
VIH
0.7 VDDD
VDDD
V
Input voltage low level (Note 4)
VIL
0
0.3 VDDD
V
DC Electrical Specifications
Over Recommended Operating Conditions (unless otherwise specified)
Parameter
Symbol
Conditions
Minimum
Typical
(Note 3)
Output voltage high level (Note 5)
VOH
IOH = 3mA
VDDD-0.8
VDDD-0.4
Output voltage low level (Note 6)
VOL
IOL = 3mA
0.2
0.4
V
Dynamic supply current (Note 7,8)
IDD_DYN
(Note 9)
9.4
14
mA
Static supply current (Note 8)
IDD_STATIC
(Note 9)
2.7
Sleep-mode supply current (Note 8)
IDD_SLP
(Note 9)
0.2
Input leakage current
ILEAK
-10
Maximum
Units
V
mA
15
uA
10
uA
AC Electrical Specifications
Parameter
Symbol
Internal clock frequency
fCLK
3
Conditions
Minimum
Typical
(Note 3)
Maximum
Units
16
26
38
MHz
Optical Specification
Parameter
Symbol
Conditions
Dark offset*
VD
Ee = 0
Typical
(Note 3)
Minimum
Maximum
65
Units
LSB
*code is from dark code to (dark code + 128LSB)
Minimum sensitivity
Parameter
Symbol
Conditions
Minimum
Irradiance Responsivity
Re
λP = 460 nm
Refer Note 10
B
λP = 542 nm
Refer Note 11
G
λP = 645 nm
Refer Note 12
R
Typical
(Note 3)
Maximum
36
Units
LSB /
(mW/cm2)
53
82
Maximum sensitivity
Parameter
Symbol
Conditions
Minimum
Irradiance Responsivity
Re
λP = 460 nm
Refer Note 10
B
λP = 542 nm
Refer Note 11
G
λP = 645 nm
Refer Note 12
R
Typical
(Note 3)
Maximum
1250
Units
LSB /
(mW/cm2)
1750
2490
Minimum sensitivity
Parameter
Symbol
Saturation Irradiance
(note 13)
Conditions
Minimum
λP = 460 nm
Refer Note 10
B
λP = 542 nm
Refer Note 11
G
λP = 645 nm
Refer Note 12
R
Typical
(Note 3)
Maximum
4.17
Units
mW/
cm2
2.83
1.83
Maximum sensitivity
Parameter
Saturation Irradiance
(note 13)
4
Symbol
Conditions
Minimum
λP = 460 nm
Refer Note 10
B
λP = 542 nm
Refer Note 11
G
λP = 645 nm
Refer Note 12
R
Typical
(Note 3)
0.12
0.09
0.06
Maximum
Units
mW/
cm2
Spectral response
1
0.8
Relative sensitivity
Notes:
1. The “Absolute Maximum Ratings” are those values beyond which
damage to the device may occur. The device should not be
operated at these limits. The parametric values defined in the
“Electrical Specifications” table are not guaranteed at the absolute
maximum ratings. The “Recommended Operating Conditions”
table will define the conditions for actual device operation.
2. Unless otherwise specified, all voltages are referenced to ground.
3. Specified at room temperature (25°C) and VDDD = VDDA = 2.6V.
4. Applies to all DI pins.
5. Applies to all DO pins. SDASLV go tri-state when output logic
high. Minimum VOH depends on the pull-up resistor value.
6. Applies to all DO and DIO pins.
7. Dynamic testing is performed with the IC operating in a mode
representative of typical operation.
8. Refers to total device current consumption.
9. Output and bidirectional pins are not loaded.
10. Test condition is blue light of peak wavelength (λP) 460 nm and
spectral half width (∆λ½) 25 nm.
11. Test condition is green light of peak wavelength (λP) 542 nm and
spectral half width (∆λ½) 35 nm
12. Test condition is red light of peak wavelength (λP) 645 nm and
spectral half width (∆λ½) 20 nm
13. Saturation irradiance = (MSB)/(Irradiance responsivity)
0.6
0.4
0.2
0
400
500
600
Wavelength (nm)
700
Typical spectral response when the gains for all the
color channels are set at equal.
Serial Interface Timing Information
Parameter
Symbol
Minimum
Maximum
Units
SCL clock frequency
fscl
0
100
kHz
(Repeated) START condition hold time
tHD:STA
4
-
µs
Data hold time
tHD:DAT
0
3.45
µs
SCL clock low period
tLOW
4.7
-
µs
SCL clock high period
tHIGH
4.0
-
µs
Repeated START condition setup time
tSU:STA
4.7
-
µs
Data setup time
tSU:DAT
250
-
ns
STOP condition setup time
tSU:STO
4.0
-
µs
Bus free time between START and STOP conditions
tBUF
4.7
-
µs
tHIGH
tHD:STA
tSU:DAT
tBUF
tSU:STA
SDA
SCL
S
Sr
tLOW
tHD:DAT
Figure 1. Serial Interface Bus Timing Waveforms
5
tHD:STA
P
tSU:STO
S
High Level Description
The sensor needs to be configured before it can be
used. The gain selection needs to be set for
optimum performance depending on light levels.
The flowcharts below describe the different
procedures required.
SENSOR GAIN
OPTIMIZATION
SENSOR
OPERATION
Step 1
Hardware Reset
Step 1
Hardware Reset
Step 2
Device Initialization
Step 2
Device Initialization
Step 3 - 4
Select sensor gain settings
Step 3 - 4
Select sensor gain settings
Step 5
Acquire ADC readings
Step 5
Acquire dark offset and
store current offset values
ADC readings
optimum?
NO
Step 6
Acquire ADC readings
YES
STOP
Sensor gain optimization flowchart
* Please refer to application note for more detailed
information.
6
Step 7
Compute sensor values
STOP
Sensor operation flowchart
Detail Description
Setup Value for Integration Time
A hardware reset (by asserting XRST) should be
performed before starting any operation.
The following value can be written to each of the
integration time registers to adjust the gain of the
sensor. The default value after reset for these
registers is 07H.
The user controls and configures the device by
programming a set of internal registers through a
serial interface. At the start of application, the
following setup data must be written to the setup
registers:
Value (Hex)
Integration Time Slot
00
1
01
2
Register
Setup Data
(Hex)
02
3
03
SETUP0
01
03
4
04
SETUP1
01
04
5
0C
SETUP2
01
05
6
0D
SETUP3
01
06
7
0E
SETUP4
01
07
8
08
9
09
10
0A
11
0B
12
0C
13
0D
14
Address
(Hex)
Sensor Gain Settings
The sensor gain can be adjusted by varying the
photodiode size and integration time of the sensor
manually through the following registers.
Sensor Sensitivity ~ Photodiode Size x Integration
Time Slot
Address
(Hex)
Register
Description
0E
15
0B
PDASR
Red Channel Photodiode Size
0F
16
0A
PDASG
Green Channel Photodiode Size
09
PDASB
Blue Channel Photodiode Size
Sensor ADC Output Registers
11
TINTR
Red Channel Integration Time
10
TINTG
Green Channel Integration Time
To obtain sensor ADC value, ‘02’ Hex must be written
to ACQ register before reading the Sensor ADC Output
Registers.
0F
TINTB
Blue Channel Integration Time
Setup Value for Photodiode Size
Address
(Hex)
Register Description
The following value can be written to each of the
photodiode size registers to adjust the gain of the
sensor. The default value after reset for these
registers is 07H.
02
ACQ
Acquire sensor analog to digital
converter (ADC) values when 02H
is written. Reset to 00H when
sensor acquisition is completed
Value (Hex)
Photodiode Size
44
ADCR
Sensor Red channel ADC value
01
¼
43
ADCG
Sensor Green channel ADC value
03
½
42
ADCB
Sensor Blue channel ADC value
07
¾
0F
Full
7
Serial Interface Reference
START/STOP Condition
Description
The master initiates and terminates all serial data
transfers. To begin a serial data transfer, the master
must send a unique signal to the bus called a START
condition. This is defined as a HIGH to LOW
transition on the SDA line while SCL is HIGH.
The programming interface to the ADJD-S313 is a
2-wire serial bus. The bus consists of a serial clock
(SCL) and a serial data (SDA) line. The SDA line is
bi-directional on ADJD-S313 and must be
connected through a pull-up resistor to the positive
power supply. When the bus is free, both lines are
HIGH.
The 2-wire serial bus on ADJD-S313 requires one
device to act as a master while all other devices
must be slaves. A master is a device that initiates a
data transfer on the bus, generates the clock signal
and terminates the data transfer while a device
addressed by the master is called a slave. Slaves
are identified by unique device addresses.
Both master and slave can act as a transmitter or a
receiver but the master controls the direction for
data transfer. A transmitter is a device that sends
data to the bus and a receiver is a device that
receives data from the bus.
The ADJD-S313 serial bus interface always operates
as a slave transceiver with a data transfer rate of
up to 100kbit/s.
The master terminates the serial data transfer by
sending another unique signal to the bus called a
STOP condition. This is defined as a LOW to HIGH
transition on the SDA line while SCL is HIGH.
The bus is considered to be busy after a START (S)
condition. It will be considered free a certain time
after the STOP (P) condition. The bus stays busy if
a repeated START (Sr) is sent instead of a STOP
condition.
The START and repeated START conditions are
functionally identical.
Data Transfer
The master initiates data transfer after a START
condition. Data is transferred in bits with the master
generating one clock pulse for each bit sent. For a
data bit to be valid, the SDA data line must be
stable during the HIGH period of the SCL clock line.
Only during the LOW period of the SCL clock line
can the SDA data line change state to either HIGH
or LOW.
SDA
SCL
S
P
START condition
STOP condition
Figure 1. START/STOP Condition
SDA
SCL
Data valid
Figure 2. Data Bit Transfer
8
Data change
The SCL clock line synchronizes the serial data
transmission on the SDA data line. It is always
generated by the master. The frequency of the SCL
clock line may vary throughout the transmission as
long as it still meets the minimum timing
requirements.
The master by default drives the SDA data line. The
slave drives the SDA data line only when sending
an acknowledge bit after the master writes data to
the slave or when the master requests the slave to
send data.
The SDA data line driven by the master may be
implemented on the negative edge of the SCL clock
line. The master may sample data driven by the
slave on the positive edge of the SCL clock line.
Figure
shows an example of a master
implementation and how the SCL clock line and
SDA data line can be synchronized.
A complete data transfer is 8-bits long or 1-byte.
Each byte is sent most significant bit (MSB) first
followed by an acknowledge or not acknowledge
bit. Each data transfer can send an unlimited
number of bytes (depending on the data format).
SDA data sampled on the
positive edge of SCL
SDA
SCL
SDA data driven on the
negative edge of SCL
Figure 3. Data Bit Synchronization
Acknowledge/Not acknowledge
The receiver must always acknowledge each byte
sent in a data transfer. In the case of the slavereceiver and master-transmitter, if the slavereceiver does not send an acknowledge bit, the
master-transmitter can either STOP the transfer or
generate a repeated START to start a new transfer.
P
SDA
SCL
MSB
S
or
Sr
1
LSB
2
ACK
8
9
MSB
1
LSB
2
8
START or repeated
START condition
SDA pulled LOW
by receiver
SDA
(SLAVE-RECEIVER)
SCL
(MASTER)
Figure 5. Slave-Receiver Acknowledge
9
9
Sr
Sr
or
P
STOP or repeated
START condition
Figure 4. Data Byte Transfer
SDA
(MASTER-TRANSMITTER)
NO
ACK
Acknowledge
LSB
SDA left HIGH
by transmitter
8
9
Acknowledge
clock pulse
In the case of the master-receiver and slavetransmitter, the master generates a not
acknowledge to signal the end of the data transfer
to the slave-transmitter. The master can then send
a STOP or repeated START condition to begin a new
data transfer.
In all cases, the master generates the acknowledge
or not acknowledge SCL clock pulse.
Addressing
Each slave device on the serial bus needs to have a
unique address. This is the first byte that is sent by
the master-transmitter after the START condition.
The address is defined as the first seven bits of the
first byte.
The eighth bit or least significant bit (LSB)
determines the direction of data transfer. A ‘one’
in the LSB of the first byte indicates that the master
will read data from the addressed slave (masterreceiver and slave-transmitter). A ‘zero’ in this
position indicates that the master will write data
to the addressed slave (master-transmitter and
slave-receiver).
A device whose address matches the address sent
by the master will respond with an acknowledge
for the first byte and set itself up as a slavetransmitter or slave-receiver depending on the LSB
of the first byte.
The slave address on ADJD-S313 is 0x58 (7-bits).
SDA
(SLAVE-TRANSMITTER)
P
SDA
(MASTER-RECEIVER)
SDA left HIGH
by receiver
SCL
(MASTER)
8
MSB
LSB
A6
A5
A4
A3
A2
A1
A0
1
0
1
1
0
0
0
Slave address
10
Not
acknowledge
R/W
Sr
9
Acknowledge
clock pulse
Figure 6. Master-Receiver Acknowledge
Figure 7. Slave Addressing
SDA left HIGH
by transmitter
LSB
STOP or repeated
START condition
Data format
ADJD-S313 uses a register-based programming
architecture. Each register has a unique address and
controls a specific function inside the chip.
To write to a register, the master first generates a
START condition. Then it sends the slave address
for the device it wants to communicate with. The
least significant bit (LSB) of the slave address must
indicate that the master wants to write to the slave.
The addressed device will then acknowledge the
master.
The master writes the register address it wants to
access and waits for the slave to acknowledge. The
master then writes the new register data. Once the
slave acknowledges, the master generates a STOP
condition to end the data transfer.
Start condition
S
To read from a register, the master first generates
a START condition. Then it sends the slave address
for the device it wants to communicate with. The
least significant bit (LSB) of the slave address must
indicate that the master wants to write to the slave.
The addressed device will then acknowledge the
master.
The master writes the register address it wants to
access and waits for the slave to acknowledge. The
master then generates a repeated START condition
and resends the slave address sent previously. The
least significant bit (LSB) of the slave address must
indicate that the master wants to read from the
slave. The addressed device will then acknowledge
the master.
The master reads the register data sent by the slave
and sends a no acknowledge signal to stop reading.
The master then generates a STOP condition to end
the data transfer.
Master will write data
A6 A5 A4 A3 A2 A1 A0 W
Stop condition
A D7 D6 D5 D4 D3 D2 D1 D0 A D7 D6 D5 D4 D3 D2 D1 D0 A
Master sends
slave address
Master writes
register address
Slave acknowledge
P
Master writes
register data
Slave acknowledge
Slave acknowledge
Figure 8. Register Byte Write Protocol
Start condition
S
A6 A5 A4 A3 A2 A1 A0 W
Master will read data
Stop condition
A D7 D6 D5 D4 D3 D2 D1 D0 A
Sr A6 A5 A4 A3 A2 A1 A0 R
A D7 D6 D5 D4 D3 D2 D1 D0 A
Master writes
register address
Master sends
slave address
Master reads
register data
Master sends
slave address
Slave acknowledge
Figure 9. Register Byte Read Protocol
11
Repeated start
condition
Master will write data
Slave acknowledge
Slave acknowledge
P
Master not
acknowledge
Application Diagrams
Powering the Device
Ground Connection
HOST
SYSTEM
15 SLEEP
10k
AGND and DGND must both be set to 0V and
preferably star-connected to a central power source
as shown in the application diagram. A potential
difference between AGND and DGND may cause the
ESD diodes to turn on inadvertently.
10k
10k
10k
DVDD
SDA
10 XRST
12 SDASLV
SCL
11 SCLSLV
XRST
HOST
SYSTEM
AVDD
19
Voltage
Regulator
AGND
8, 16,
17, 18
DGND
5, 6
DVDD
7
Voltage
Regulator
Star-connected ground
Pin Information
PIN
NAME
TYPE
DESCRIPTION
1
NC
No connect
No connect. Leave floating.
2
NC
No connect
No connect. Leave floating.
3
NC
No connect
No connect. Leave floating.
4
NC
No connect
No connect. Leave floating.
5
DGND
Ground
Tie to digital ground.
6
DGND
Ground
Tie to digital ground.
7
DVDD
Power
Digital power pin.
8
AGND
Ground
Tie to analog ground.
9
NC
No connect
No connect. Leave floating.
10
XRST
Input
Global, asynchronous, active-low system reset. When asserted low, XRST
resets all registers. Minimum reset pulse low is 10 µs and must be provided by
external circuitry.
11
SCLSLV
Input
12
SDASLV
Input/Output
(tri-state high)
SDASLV and SCLSLV are the serial interface communications pins. SDASLV is
the bidirectional data pin and SCLSLV is the interface clock. A pull-up resistor
should be tied to SDASLV because it goes tri-state to output logic 1.
13
NC
No connect
No connect. Leave floating.
14
NC
No connect
No connect. Leave floating.
15
SLEEP
Input
When SLEEP=1, the device goes into sleep mode. In sleep mode, all analog
circuits are powered down and the clock signal is gated away from the core
logic resulting in very low current consumption.
16
AGND
Ground
Tie to analog ground.
17
AGND
Ground
Tie to analog ground.
18
AGND
Ground
Tie to analog ground.
19
AVDD
Power
Analog power pin.
20
NC
No connect
No connect. Leave floating.
12
Package Dimensions
Bottom View
NOTE: DIMENSIONS ARE IN MILIMETERS (MM)
13
Recommended Reflow Profile
It is recommended that Henkel Pb-free solder paste
LF310 be used for soldering ADJD-S313. Below is
the recommended soldering profile.
T-peak
230 ± 5 °C
T-reflow 218 °C
TEMPERATURE
DELTA-FLUX = 2 °C/sec. max.
T-max.
160 °C
T-min.
120 °C
DELTA-COOLING = 2 °C/sec. max.
DELTA-RAMP =
1 °C/sec. max.
40-60 sec. max.
20-40 sec. max.
t-pre
t-reflow
TIME
20 Lead QFN Recommended PCB Land Pad Design
20 Lead QFN Recommended Stencil Design
IPC-SM-782 is used as the standard for the PCB land
pad design. Recommended PCB finishing is gold
plated.
A stencil thickness of 2.18mm (6 mils) for this QFN
package is recommended.
0.8 mm
0.4 mm
0.8 mm
3.19 mm
0.4 mm
5.5 mm
3.19 mm
2.18mm
3.9 mm
5.5 mm
14
Recommendations for Handling and Storage of
ADJD-S313
This product is qualified as Moisture Sensitive Level 3
per Jedec J-STD-020. Precautions when handling this
moisture sensitive product is important to ensure the
reliability of the product. Do refer to Avago Application
Note AN5305 Handling Of Moisture Sensitive Surface
Mount Devices for details.
B. Control after opening the MBB
• The humidity indicator card (HIC) shall be read
immediately upon opening of MBB
• The components must be kept at <30°C/60%RH at
all time and all high temperature related process
including soldering, curing or rework need to be
completed within 168hrs
C. Control for unfinished reel
A. Storage before use
• Unopened moisture barrier bag (MBB) can be stored
at 30°C and 90%RH or less for maximum 1 year
• It is not recommended to open the MBB prior to
assembly (e.g. for IQC)
• It should also be sealed with a moisture absorbent
material (Silica Gel) and an indicator card (cobalt
chloride) to indicate the moisture within the bag
• For any unused components, they need to be stored
in sealed MBB with desiccant or desiccator at <5%RH
D. Control of assembled boards
• If the PCB soldered with the components is to be
subjected to other high temperature processes, the
PCB need to be stored in sealed MBB with desiccant
or desiccator at <5%RH to ensure no components
have exceeded their floor life of 168hrs
E. Baking is required if:
• “10%” or “15%” HIC indicator turns pink
• The components are exposed to condition of >30°C/
60%RH at any time.
Package Tape and Reel Dimensions
• The components floor life exceeded 168hrs
Carrier Tape Dimensions
• Recommended baking condition (in component
form): 125°C for 24hrs
4.00 ± 0.10
SEE NOTE #2
1.55 ± 0.05
2.00 ± 0.05
SEE NOTE #2
B
R 0.50 TYP.
1.75 ± 0.10
5.50 ± 0.05
12.00 ± 0.10
Bo
A
Ko
A
8.00 ± 0.10
B
1.50 (MIN.)
SECTION B-B
Ao
0.30 ± 0.05
SECTION A-A
NOTES:
1. Ao AND Bo MEASURED AT 0.3 mm ABOVE BASE OF POCKET.
2. 10 PITCHES CUMULATIVE TOLERANCE IS ± 0.2 mm.
3. DIMENSIONS ARE IN MILLIMETERS (mm).
15
Ao:
Bo:
Ko:
PITCH:
WIDTH:
5.30
5.30
2.20
8.00
12.00
Reel Dimensions
65
+1.5*
12.4 - 0.0
45
R10.65
R5.2
55.0 ± 0.5
45
178.0 ± 0.5
176.0
EMBOSSED RIBS
RAISED: 0.25 mm
WIDTH: 1.25 mm
BACK VIEW
512
18.0 MAX.*
NOTES:
1. *MEASURED AT HUB AREA.
2. ALL FLANGE EDGES TO BE ROUNDED.
ESD WARNING: Standard CMOS handling precautions should be observed to avoid static discharge.
AVAGO TECHNOLOGIES' PRODUCTS AND SOFTWARE ARE NOT SPECIFICALLY DESIGNED, MANUFACTURED OR AUTHORIZED FOR SALE AS
PARTS, COMPONENTS OR ASSEMBLIES FOR THE PLANNING, CONSTRUCTION, MAINTENANCE OR DIRECT OPERATION OF A NUCLEAR FACILITY
OR FOR USE IN MEDICAL DEVICES OR APPLICATIONS. CUSTOMER IS SOLELY RESPONSIBLE, AND WAIVES ALL RIGHTS TO MAKE CLAIMS
AGAINST AVAGO TECHNOLOGIES OR ITS SUPPLIERS, FOR ALL LOSS, DAMAGE, EXPENSE OR LIABILITY IN CONNECTION WITH SUCH USE.
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www.avagotech.com
Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies, Limited in the United States and other countries.
Data subject to change. Copyright © 2007 Avago Technologies Limited. All rights reserved. Obsoletes AV01-0470EN
AV01-0688EN - January 4, 2007