ATMEL AT77C102B-CB01YV-

1. Features
•
•
•
•
•
•
•
•
•
•
•
•
Sensitive Layer Over a 0.35 µm CMOS Array
Image Zone: 0.4 x 14 mm = 0.02" x 0.55"
Image Array: 8 x 280 = 2240 pixels
Pixel Pitch: 50 µm x 50 µm = 500 dpi
Pixel Clock: up to 2 MHz Enabling up to 1780 Frames per Second
Die Size: 1.64 x 17.46 mm
Operating Voltage: 3V to 3.6V
Naturally Protected Against ESD: > 16 kV Air Discharge
Power Consumption: 16 mW at 3.3V, 1 MHz, 25°C
Operating Temperature Range: -40°C to +85°C
Chip-on-Board (COB), Chip-on-Board (COB) with Connector
Complies With the European Directive for Restriction of Hazardous Substances
(RoHS Directive)
2. Applications
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•
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PDA (Access Control, Data Protection)
Notebook, PC-add on (Access Control, e-business)
PIN Code Replacement
Automated Teller Machines, POS
Building Access
Electronic Keys (Cars, Home)
Portable Fingerprint Imaging for Law Enforcement
TV Access
Figure 2-1.
Thermal
Fingerprint
Sensor with
0.4 mm x 14 mm
(0.02" x 0.55")
Sensing Area
and
Digital Output
(On-chip ADC)
FingerChip® Packages
AT77C102B
FingerChip®
Chip-on-board Package
with Connector
Chip-on-board Package
(COB)
Actual size
Rev. 5364A–BIOM–09/05
Table 2-1.
Pin Description for Chip-on-Board Package: AT77C102B-CB01YV
Pin Number
Name
Type
1
GND
GND
2
AVE
Analog output
3
AVO
Analog output
4
TPP
Power
5
TPE
Digital input
6
VCC
Power
7
GND
GND
8
RST
Digital input
9
PCLK
Digital input
10
OE
Digital input
11
ACKN
Digital output
12
De0
Digital output
13
Do0
Digital output
14
De1
Digital output
15
Do1
Digital output
16
De2
Digital output
17
Do2
Digital output
18
De3
Digital output
19
Do3
Digital output
20
FPL
GND
21
GND
GND
The die attach is connected to pins 1, 7 and 21, and must be grounded. The FPL pin must be
grounded.
2
GND
AVE
AVO
TPP
TPE
VCC
GND
RST
PCLK
OE
ACKN
De0
Do0
De1
Do1
De2
Do2
De3
Do3
FPL
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
GND
21
AT77C102B
5364A–BIOM–09/05
AT77C102B
Table 2-2.
Note:
Pin Description for COB with Connector Package: AT77C102B-CB02YV(1)
Pin Number
Name
Type
1
FPL
GND
2
Not connected
3
Not connected
4
DE3
Digital output
5
DO3
Digital output
6
DE2
Digital output
7
DO2
Digital output
8
DE1
Digital output
9
DO1
Digital output
10
DE0
Digital output
11
DO0
Digital output
12
AVE
Analog output
13
AVO
Analog output
14
TPP
Power
15
TPE
Digital input
16
VCC
Power
17
GND
GND
18
RST
Digital input
19
PCLK
Digital input
20
OE
Digital input
21
ACKN
Digital output
1. Ref. Connector: FH18-21S-0.3SHW (HIROSE).
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5364A–BIOM–09/05
Figure 2-2.
COB with Flex(1)
Flex with metallizations up
Flex with metallizations down
Figure 2-3.
Flex Output Side
Flex Output
(FingerChip Connector Side)
Metallizations Up
1
3
2
Note:
4
1. Flex is not provided by Atmel.
AT77C102B
5364A–BIOM–09/05
AT77C102B
3. Description
The AT77C102B is part of the Atmel FingerChip monolithic fingerprint sensor family for which no
optics, no prism and no light source are required.
The AT77C102B is a single-chip, high-performance, low-cost sensor based on temperature
physical effects for fingerprint sensing.
The AT77C102B has a linear shape, which captures a fingerprint image by sweeping the finger
across the sensing area. After capturing several images, Atmel proprietary software can reconstruct a full 8-bit fingerprint image.
The AT77C102B has a small surface combined with CMOS technology, and a Chip-on-Board
package assembly. These facts contribute to a low-cost device.
The device delivers a programmable number of images per second, while an integrated analogto-digital converter delivers a digital signal adapted to interfaces such as an EPP parallel port, a
USB microcontroller or directly to microprocessors. No frame grabber or glue interface is therefore necessary to send the frames. These facts make AT77C102B an easy device to include in
any system for identification or verification applications.
Table 3-1.
Absolute Maximum Ratings()
Parameter
Symbol
Comments
Value
Positive supply voltage
VCC
GND to 4.6
Temperature stabilization
power
TPP
GND to 4.6
Front plane
FPL
GND to VCC +0.5
Digital input voltage
RST PCLK
GND to VCC +0.5
Storage temperature
Tstg
-50 to +95
Lead temperature
(soldering, 10 seconds)
Table 3-2.
Tleads
Do not solder
Note: Stresses beyond those listed
under “Absolute Maximum Ratings”
may cause permanent damage to the
device. These are stress ratings only
and functional operation of the device at
these or any other conditions beyond
those indicated in the operational
sections of this specification is not
implied. Exposure to absolute
maximum rating conditions for extended
periods may affect device reliability.
Forbidden
Recommended Conditions Of Use
Parameter
Symbol
Positive supply voltage
VCC
Front plane
FPL
Comments
Min
Typ
Max
Unit
3V
3.3V
3.6V
V
Must be grounded
GND
V
Digital input voltage
CMOS levels
V
Digital output voltage
CMOS levels
V
50
Digital load
CL
Analog load
CA
RA
Not connected
Operating temperature range
Tamb
V grade
Maximum current on TPP
ITPP
pF
pF
kΩ
-40°C to +85°C
0
°C
100
mA
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5364A–BIOM–09/05
Table 3-3.
Resistance
Parameter
Min Value
Standard Method
On pins. HBM (Human Body Model) CMOS I/O
2 kV
MIL-STD-883 - method 3015.7
On die surface (Zapgun)
Air discharge
±16 kV
NF EN 6100-4-2
200 000
MIL E 12397B
4 hours
Internal method
ESD
Mechanical Abrasion
Number of cycles without lubricant multiply by an estimated factor
of 20 for correlation with a real finger
Chemical Resistance
Cleaning agent, acid, grease, alcohol, diluted acetone
Table 3-4.
Specifications
Explanation Of Test Levels
I
100% production tested at +25°C
II
100% production tested at +25°C, and sample tested at specified temperatures (AC testing done on sample)
III
Sample tested only
IV
Parameter is guaranteed by design and/or characterization testing
V
Parameter is a typical value only
VI
100% production tested at temperature extremes
D
100% probe tested on wafer at Tamb = +25°C
Table 3-5.
Physical Parameter
Parameter
Test Level
Resolution
IV
50
µm
Size
IV
8 x 280
Pixel
Yield: number of bad pixels
I
Equivalent resistance on TPP pin
I
6
Min
20
Typ
30
Max
Unit
5
Bad pixels
47
Ω
AT77C102B
5364A–BIOM–09/05
AT77C102B
.
Table 3-6.
3.3V Power supply
The following characteristics are applicable to the operating temperature -40°C ≤ Ta ≤ +85°C
Typical conditions are: VCC = +3.3 V; Tamb = 25°C; FPCLK = 1 MHz; Duty cycle = 50%
Cload 120 pF on digital outputs, analog outputs disconnected unless otherwise specified
Parameter
Symbol
Test Level
Min
Typ
Max
Unit
3.0
3.3
3.6
V
Power Requirements
Positive supply voltage
VCC
Active current on VCC pin, 1 MHz
Current on VCC pin, in static mode Cload = 0 pF
ICC
I
IV
5
4
7
5
mA
mA
Power dissipation on VCC
Cload = 0
PCC
I
IV
16
13
25
18
mW
mW
ICCNAP
I
10
µA
VAVx
IV
2.9
V
Current on VCC in NAP mode
Analog Output
Voltage range
0
Digital Inputs
Logic compatibility
CMOS
Logic “0” voltage
VIL
I
0
0.8
V
Logic “1” voltage
VIH
I
2.3
VCC
V
Logic “0” current
IIL
I
-10
0
µA
Logic “1”current
IIH
I
0
10
µA
TPE logic “0” voltage
IILTPE
1
-10
0
µA
TPE logic “1” voltage
IIHTPE
1
0
300
µA
0.6
V
Digital Outputs
Logic compatibility
VOL
I
(1)
VOH
I
Logic “0” voltage
Logic “1” voltage
Note:
CMOS
(1)
2.4
V
1. With IOL = 1 mA and IOH = -1 mA
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5364A–BIOM–09/05
.
Table 3-7.
Switching Performances
The following characteristics are applicable to the operating temperature -40°C ≤ Ta ≤ +85°C
Typical conditions are: nominal voltage; Tamb = 25°C; FPCLK = 1 MHz; Duty cycle = 50%
Cload 120 pF on digital and analog outputs unless otherwise specified
Parameter
Symbol
Test Level
Min
Typ
Max
Unit
Clock frequency
fPCLK
I
0.5
1
2
MHz
Clock pulse width (high)
tHCLK
I
250
ns
Clock pulse width (low)
tLCLK
I
250
ns
Clock setup time (high)/reset falling edge
tSetup
I
No data change
tNOOE
IV
100
ns
Reset pulse width high
tHRST
IV
50
ns
Parameter
Symbol
Test Level
Min
Output delay from PCLK to ACKN rising edge
tPLHACKN
Output delay from PCLK to ACKN falling edge
Table 3-8.
0
ns
3.3V ±10% Power Supply
Max
Unit
I
145
ns
tPHLACKN
I
145
ns
tPDATA
I
120
ns
tPAVIDEO
I
250
ns
Output delay from OE to data high-Z
tDATAZ
IV
34
ns
Output delay from OE to data output
tZDATA
IV
47
ns
Output delay from PCLK to data output Dxi
Output delay from PCLK to analog output AVx
Figure 3-1.
Typ
Reset
Reset RST
tHRST
Clock PCLK
tSETUP
8
AT77C102B
5364A–BIOM–09/05
AT77C102B
Figure 3-2.
Read One Byte/Two Pixels
fPCLK
tLCLK
tHCLK
Clock
PCLK
Acknowledge
ACKN
tPLHACKN
Data output
Do0-3, De0-3
Video analog output
AVO, AVE
tPHLACKN
Data #N-1
Data #N
Data #N+1
Data #N
Data #N+1
t PDATA
Data #N+2
tPAVIDEO
Figure 3-3.
Output Enable
Output enable
OE
Data output
Do0-3, De0 -3
Hi-Z
tZDATA
tDATAZ
Data output
Hi-Z
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5364A–BIOM–09/05
Figure 3-4.
No Data Change
tNOOE
PCLK
OE
Note:
OE must not change during TNOOE after the PCLK falls. This is to ensure that the output drivers of the data are not driving current, so as to reduce the noise level on the power supply.
Figure 3-5.
AT77C102B Block Diagram
Clock
PCLK
ACKN
Reset
RST
Line sel
Column selection
Even
1 dummy column
1
8 lines of 280 columns of pixels
TPP
3.1
TPE
De0-3
8
Latches
8
Odd
Chip temperature
stabilization
4
Amp
2240
8
4-bit
ADC
Chip
temperature
sensor
Analog
output
AVE AVO
4-bit
ADC
Do0-3
4
Output
enable
OE
Functional Description
The circuit is divided into two main sections: sensor and data conversion. One particular column
among 280 plus one is selected in the sensor array (1), then each pixel of the selected column
sends its electrical information to the amplifiers (2) [one per line], then two lines at a time are
selected (odd and even) so that two particular pixels send their information to the input of two 4bit analog-to-digital converters (3), so two pixels can be read for each clock pulse (4).
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AT77C102B
5364A–BIOM–09/05
AT77C102B
Figure 3-6.
Functional Description
1
2
Column selection
3
Line sel
8 lines of 280 columns of pixels
Even
4-bit
ADC
4
4
De0-3
8
latches
Amp
8
1 dummy column
Odd
4-bit
ADC
Do0-3
4
Chip
temperature
sensor
3.2
Sensor
Each pixel is a sensor in itself. The sensor detects a temperature difference between the beginning of an acquisition and the reading of the information: this is the integration time. The
integration time begins with a reset of the pixel to a predefined initial state. Note that the integration time reset has nothing to do with the reset of the digital section.
Then, at a rate depending on the sensitivity of the pyroelectric layer, on the temperature variation between the reset and the end of the integration time, and for the duration of the integration
time, electrical charges are generated at the pixel level.
3.3
Analog-to-digital Converter/ Reconstructing an 8-bit Fingerprint Image
An analog-to-digital converter (ADC) is used to convert the analog signal coming from the pixel
into digital data that can be used by a processor.
As the data rate for the parallel port and the USB is in the range of 1 MB per second, and at least
a rate of 500 frames per second is needed to reconstruct the image with a fair sweeping speed
of the finger, two 4-bit ADCs have been used to output two pixels at a time on one byte.
3.4
Start Sequence
A reset is not necessary between each frame acquisition.
The start sequence must consist in:
1. Setting the RST pin to high.
2. Setting the RST pin to low.
3. Sending 4 clock pulses (due to pipe-line).
4. Sending clock pulses to skip the first frame.
Note that after a reset it is recommended to skip the first 200 slices to stabilize the acquisition.
Figure 3-7.
Start Sequence
4 + 1124 clock pulses to skip the first frame
Reset RST
Clock PCLK
1
2
3
4
1
1124
1
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5364A–BIOM–09/05
3.5
Reading the Frames
A frame consists of 280 true columns plus one dummy column of eight pixels. As two pixels are
output at a time, a system must send 281 x 4 = 1124 clock pulses to read one frame.
Reset must be low when reading the frames.
3.6
Read One Byte/Output Enable
The clock is taken into account on its falling edge and data is output on its rising edge.
For each clock pulse, after the start sequence, a new byte is output on the Do0-3 and De0-3
pins. This byte contains two pixels: 4-bit on Do0-3 (odd pixels), 4-bit on De0-3 (even pixels).
To output the data, the output enable (OE) pin must be low. When OE is high, the Do0-3 and
De0-3 pins are in high-impedance state. This facilitates an easy connection to a microprocessor
bus without additional circuitry since the data output can be enabled using a chip select signal.
Note that the AT77C102B always sends data: there is no data exchange to switch to read/write
mode.
3.7
Power Supply Noise
IMPORTANT: When a falling edge is applied on OE (that is when the Output Enable becomes
active), then some current is drained from the power supply to drive the eight outputs, producing
some noise. It is important to avoid such noise just after the PCLK clock’s falling edge, when the
pixels’ information is evaluated: the timing diagram (Figure 3-2) and time TNOOE define the interval time when the power supply must be as quiet as possible.
3.8
Video Output
An analog signal is also available on pins AVE and AVO. Note that video output is available one
clock pulse before the corresponding digital output (one clock pipe-line delay for the analog to
digital conversion).
3.9
Pixel Order
After a reset, pixel 1 is located on the upper left corner, looking at the chip with bond pads to the
right. For each column of eight pixels, pixels 1, 3, 5 and 7 are output on odd data Do0-3 pins,
and pixels 2, 4, 6 and 8 are output on even data De0-3 pins. The Most Significant Bit (MSB) is bit
3, and the Least Significant Bit is bit 0.
Figure 3-8.
Pixel Order
Pixel #1 (1,1)
Pixel #2233 (280,1)
B ond pads
Pixel #8 (1,8)
12
Pixel #2240 (280,8)
AT77C102B
5364A–BIOM–09/05
AT77C102B
3.10
Synchronization: The Dummy Column
A dummy column has been added to the sensor to act as a specific pattern to detect the first
pixel. Therefore, 280 true columns plus one dummy column are read for each frame.
The four bytes of the dummy column contain a fixed pattern on the first two bytes, and temperature information on the last two bytes.
Table 1. Dummy Column Description
Dummy Byte
Odd
Even
Dummy Byte 1 DB1:
111X
0000
Dummy Byte 2 DB2:
111X
0000
Dummy Byte 3 DB3:
rrrr
nnnn
Dummy Byte 4 DB4:
tttt
pppp
Note:
x represents 0 or 1
The sequence 111X0000 111X0000 appears on every frame (exactly every 1124 clock pulses),
so it is an easy pattern to recognize for synchronization purposes.
3.11
Thermometer
The dummy bytes DB3 and DB4 contain some internal temperature information.
The even nibble nnnn in DB3 can be used to measure an increase or decrease of the chip’s temperature, using the difference between two measures of the same physical device. The following
table gives values in Kelvin.
Table 1. Temperature Table
nnnn
Decimal
nnnn
Binary
Temperature differential with code 8
in Kelvin
15
1111
> 11.2
14
1110
8.4
13
1101
7
12
1100
5.6
11
1011
4.2
10
1010
2.8
9
1001
1.4
8
1000
0
7
0111
-1.4
6
0110
-2.8
5
0101
-4.2
4
0100
-5.6
3
0011
-7
2
0010
-8.4
1
0001
-11.2
0
0000
< -16.8
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5364A–BIOM–09/05
For code 0 and 15, the absolute value is a minimum (saturation).
When the image contrast becomes faint because of a low temperature difference between the
finger and the sensor, it is recommended to use the temperature stabilization circuitry to
increase the temperature by two codes (that is from 8 to 10), so as to obtain a sensor increase of
at least >1.4 Kelvin. This enables enough contrast to obtain a proper fingerprint reconstruction.
3.12
Integration Time and Clock Jitter
The AT77C102B is not very sensitive to clock jitters (clock variations). The most important
requirement is a regular integration time that ensures the frame reading rate is also as regular as
possible, so as to obtain consistent fingerprint slices.
If the integration time is not regular, the contrast can vary from one frame to another.
Note that it is possible to introduce some waiting time between each set of 1124 clock pulses,
but the overall time of one frame read must be regular. This waiting time is generally the time
needed by the processor to perform some calculation over the frame (to detect the finger, for
instance).
Figure 3-9.
Read One Frame
Reset RST is low
1
Column 1
2
3
Column 2
4
5
Column 280
6
1119
Dummy Column 281
1120
1121
1122
1123
1124
7&8
DB1
DB2
DB3
DB4
Clock PCLK
Pixels 1 & 2
3&4
5&6
7&8
1&2
3&4
Figure 3-10. Regular Integration Time
REGULAR INTEGRATION TIME
Frame n
Frame n+1
Frame n+2
Frame n+3
Clock PCLK
1124 pulses
1124 pulses
3.13
Power Management
3.14
Nap Mode
1124 pulses
1124 pulses
Several strategies are possible to reduce power consumption when the device is not in use.
The simplest and most efficient is to cut the power supply using external means.
A nap mode is also implemented in the AT77C102B. To activate this nap mode, you must:
1. Set the reset RST pin to high. By doing this, all analog sections of the device are internally powered down.
2. Set the clock PCLK pin to high (or low), thus stopping the entire digital section.
3. Set the TPE pin to low to stop the temperature stabilization feature.
4. Set the Output Enable OE pin to high, so that the output is forced in HiZ.
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AT77C102B
5364A–BIOM–09/05
AT77C102B
Figure 3-11. Nap Mode
Nap mode
Reset RST
Nap
Clock PCLK
In nap mode, all internal transistors are in shut mode. Only leakage current is drained in the
power supply, generally less than the tested value.
3.15
Static Current Consumption
When the clock is stopped (set to 1) and the reset is low (set to 0), the device’s analog sections
drain some current, whereas, if the outputs are connected to a standard CMOS input, the digital
section does not consume any current (no current is drained in the I/O). In this case the typical
current value is 5 mA. This current does not depend on the voltage (it is almost the same from 3
to 3.6V).
3.16
Dynamic Current Consumption
When the clock is running, the digital sections, and particularly the outputs if they are heavily
loaded, consume current. In any case, the current should be less than the testing machine (120
pF load on each I/O), and a maximum of 50 pF is recommended.
The AT77C102B, running at about 1 MHz, consumes less than 7 mA on the VCC pin.
3.17
Temperature Stabilization Power Consumption (TPP Pin)
When the TPE pin is set to 1, current is drained via the TPP pin. The current is limited by the
internal equivalent resistance given in Table 3-4 on page 6 and a possible external resistor.
Most of the time, TPE is set to 0 and no current is drained in TPP. When the image contrast
becomes low because of a low temperature differential (less than 1 Kelvin), then it is recommended to set TPE to 1 for a short time so that the dissipated power in the chip elevates the
temperature, allowing contrast recovery. The necessary time to increase the chip’s temperature
by one Kelvin depends on the dissipated power, the thermal capacity of the silicon sensor and
the thermal resistance between the sensor and its surroundings. As a rule of thumb, dissipating
300 mW in the chip elevates the temperature by 1 Kelvin in one second. With the 30Ω typical
value, 300 mW is 3V applied on TPP. If the power supply is 3.6V, an external resistor must be
added in the application to limit the current under 100 mA.
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5364A–BIOM–09/05
4. Packaging: Mechanical Data
Figure 4-1.
Product Reference: AT77C102B-CB01YV
0.2 A
Top View (all dimensions in mm)
0.89 ±0.3
14
TOP VIEW
SCALE 10/1
0.32
2.33 ±0.5
2.95 ±0.50
5.90 max
9 ±0.3
A
+0.07
1.64 -0.01
At 0.4 heigh from B ref.
0.82 ±0.50
0.2 min
5.20 max
26.6 ±0.3
Dam and Fill
B
0.74 ±0.06
SIDE VIEW
1.5 max.
SCALE 10/1
0.2 max
0.82 ±0.18
Figure 4-2.
Product Reference: AT77C102B-CB01YV
Bottom View (All dimensions in mm)
1 +_ 0.08
0.5+_ 0.08
1.15 +_ 0.15
3.5 +_ 0.08
2.15 +_ 0.15
1 +_ 0.15
1.5 +_ 0.08
6.30 +_ 0.1
+0.08
RO. 75 -0.12 (x3)
2 +_0.08
2 +_ 0.15
0.75+0.33
- 0.25
23.85 +_ 0.1
1.5 +0.15 (x3)
- 0.23
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AT77C102B
5364A–BIOM–09/05
AT77C102B
Figure 4-3.
Product Reference: AT77C102B-CB02YV
All Dimensions in mm
+0.04
5.2 max
14.32 -0.01
9.85 ±0.3
0.74 +_ 0.06
5.9 max
8.9 ±0.5
FLEX OUTPUT
4.1 ±0.2
8.8 ±0.2
2.9±0.5
+0.33
4.1±0.5
0.75 -0.25
1.25 ±0.5
+0.15
1.5-0.23 (x 3)
0.82 ± 0.18
1.9±0.4
1.5 MAX
Scale 4/1
0.2 min
2.39 ±0.5
26.6 ±0.3
+0.08
4.1.1
FLEX OUTPUT
6.3 ±0.1
1.78 ±0.5 (x 2)
+0.07
1.64 -0.01
4.1
A
R0.75 -0.12 (x 3)
A
Package Information
Electrical Disturbances
When looking at the fingerchip device from the top with the glob top to the right, the right edge
must never be in contact with customer casing or any component to avoid electrical
disturbances.
Figure 4-4.
Epoxy Overflow
Maximum epoxy overflow width: 0.55 mm on the die edge.
Maximum epoxy overflow thickness: 0.33 mm.
0.55
0.33
AA Section
Fingerchip
Note:
Epoxy Glue Overflow
Refer to Figure 4-1 on page 16.
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5364A–BIOM–09/05
5. Ordering Information
5.1
Package Device
AT77C
Atmel prefix
FingerChip family
102B-
CBXX Y
V
—
Quality level:
— : standard
Device type
Package
CB01: Chip On Board (COB)
CB02: COB with connector
Temperature range
o
V: -40 C to +85o C
RoHS compliant
18
AT77C102B
5364A–BIOM–09/05
Atmel Corporation
2325 Orchard Parkway
San Jose, CA 95131, USA
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