NEC UPD8873

DATA SHEET
MOS INTEGRATED CIRCUIT
µ PD8873
(5400 × 5400) PIXELS × 3 COLOR CCD LINEAR IMAGE SENSOR
DESCRIPTION
The µ PD8873 is a color CCD (Charge Coupled Device) linear image sensor which changes optical images to
electrical signal and has the function of color separation.
The µ PD8873 has 3 rows of (5400 + 5400) staggered pixels, and each row has a dual-sided readout-type charge
transfer register. And it has reset feed-through level clamp circuits and voltage amplifiers. Therefore, it is suitable for
1200 dpi/A4 color image scanners, color facsimiles and so on.
FEATURES
• Valid photocell
: (5400 + 5400) staggered pixels × 3
• Photocell pitch
: 5.25 µ m
• Line spacing
: 63 µ m (12 lines) Red line - Green line, Green line - Blue line
• Color filter
: Primary colors (red, green and blue), pigment filter (with light resistance 10 lx•hour)
• Resolution
: 48 dot/mm A4 (210 × 297 mm) size (shorter side)
10.5 µ m (2 lines) Odd line - Even line (for each color)
7
1200 dpi US letter (8.5” × 11”) size (shorter side)
• Drive clock level : CMOS output under 5 V operation
• Data rate
: 12.5 MHz Max.
• Power supply
: +12 V
• On-chip circuits
: Reset feed-through level clamp circuits
Voltage amplifiers
ORDERING INFORMATION
Part Number
µ PD8873CY
Package
CCD linear image sensor 22-pin plastic DIP (10.16 mm (400))
The information in this document is subject to change without notice. Before using this document, please
confirm that this is the latest version.
Not all products and/or types are available in every country. Please check with an NEC Electronics
sales representative for availability and additional information.
Document No. S16614EJ2V0DS00 (2nd edition)
Date Published July 2003 NS CP (K)
Printed in Japan
2003
µ PD8873
BLOCK DIAGRAM
VOD
φ SEL
20
19
GND GND
2
11
φ2
φ2
φ1
17
15
14
13
φ TG1
(Blue)
12
φ TG2
(Green)
10
φ TG3
(Red)
D67
D68
D66
S10800
S2
Photocell
(Blue)
D65
······
D64
VOUT1
21
(Blue)
S1
D14
CCD analog shift register
Transfer gate
Transfer gate
CCD analog shift register
D67
D68
D66
S10800
S2
Photocell
(Green)
D65
······
D64
VOUT2
22
(Green)
S1
D14
CCD analog shift register
Transfer gate
Transfer gate
CCD analog shift register
D68
D67
D66
S10800
S2
Photocell
(Red)
D65
······
D64
1
S1
VOUT3
(Red)
D14
CCD analog shift register
Transfer gate
Transfer gate
CCD analog shift register
4
3
φ CLB φ R
2
Data Sheet S16614EJ2V0DS
5
9
8
φ1
φ2
φ1
µ PD8873
PIN CONFIGURATION (Top View)
CCD linear image sensor 22-pin plastic DIP (10.16 mm (400))
• µ PD8873CY
22
VOUT2
Output signal 2 (Green)
Ground
GND
2
21
VOUT1
Output signal 1 (Blue)
Reset gate clock
φR
3
20
VOD
Output drain voltage
Reset feed-through level clamp clock
φ CLB
4
19
φ SEL
dpi selector
Shift register clock 1
φ1
5
18
NC
No connection
No connection
NC
6
17
φ2
Shift register clock 2
No connection
NC
7
16
NC
No connection
Shift register clock 1
φ1
8
15
φ2
Shift register clock 2
Shift register clock 2
φ2
9
14
φ1
Shift register clock 1
Transfer gate clock 3
(for Red)
φ TG3
10
13
φ TG1
Transfer gate clock 1
(for Blue)
Ground
GND
11
12
φ TG2
Transfer gate clock 2
(for Green)
Blue
10800
Green
10800
Red
10800
1
1
1
VOUT3
1
Output signal 3 (Red)
Caution Connect the No connection pins (NC) to GND.
Data Sheet S16614EJ2V0DS
3
µ PD8873
PHOTOCELL STRUCTURE DIAGRAM
2.5 µ m
5.25 µ m
2.75 µ m
Channel stopper
Aluminum
shield
PHOTOCELL ARRAY STRUCTURE DIAGRAM (Line spacing)
5.25 µ m
5.25 µ m
5.25 µ m
Blue photocell array
Blue photocell array
2 lines
(10.5 µ m)
10 lines
(52.5 µ m)
5.25 µ m
5.25 µ m
5.25 µ m
Green photocell array
Green photocell array
2 lines
(10.5 µ m)
10 lines
(52.5 µ m)
5.25 µ m
5.25 µ m
5.25 µ m
4
Red photocell array
Red photocell array
Data Sheet S16614EJ2V0DS
12 lines
(63 µ m)
2 lines
(10.5 µ m)
12 lines
(63 µ m)
µ PD8873
ABSOLUTE MAXIMUM RATINGS (TA = +25°C)
Parameter
Symbol
Ratings
Unit
Output drain voltage
VOD
−0.3 to +15
V
Shift register clock voltage
Vφ 1, Vφ 2
−0.3 to +8
V
Reset gate clock voltage
Vφ R
−0.3 to +8
V
Reset feed-through level clamp clock voltage
Vφ CLB
−0.3 to +8
V
dpi select signal voltage
Vφ SEL
−0.3 to +8
V
Vφ TG1 to Vφ TG3
Transfer gate clock voltage
Operating ambient temperature
Note
Storage temperature
−0.3 to +8
V
TA
0 to +60
°C
Tstg
−40 to +70
°C
Note Use at the condition without dew condensation.
Caution Product quality may suffer if the absolute maximum rating is exceeded even momentarily for any
parameter. That is, the absolute maximum ratings are rated values at which the product is on the
verge of suffering physical damage, and therefore the product must be used under conditions that
ensure that the absolute maximum ratings are not exceeded.
RECOMMENDED OPERATING CONDITIONS (TA = +25°C)
Parameter
Symbol
Min.
Typ.
Max.
Unit
12.6
V
Output drain voltage
VOD
11.4
12.0
Shift register clock high level
Vφ 1H, Vφ 2H
4.75
5.0
5.5
V
Shift register clock low level
Vφ 1L, Vφ 2L
0
0
0.15
V
Reset gate clock high level
Vφ RH
4.75
5.0
5.5
V
Reset gate clock low level
Vφ RL
0
0
0.15
V
Reset feed-through level clamp clock high level
Vφ CLBH
4.75
5.0
5.5
V
Reset feed-through level clamp clock low level
Vφ CLBL
0
0
0.15
V
dpi select signal high level
Vφ SELH
4.75
5.0
5.5
V
dpi select signal low level
Vφ SELL
Transfer gate clock high level
Vφ TG1H to Vφ TG3H
4.75
Transfer gate clock low level
Vφ TG1L to Vφ TG3L
0
0
0
Vφ 1H
0.15
Note
0
Vφ 1H
Note
0.15
V
V
V
Data rate
fφ R
−
2.0
12.5
MHz
Clock pulse frequency
fφ 1, fφ 2
−
2.0
12.5
MHz
Note When Transfer gate clock high level (Vφ TG1H to Vφ TG3H) is higher than Shift register clock high level (Vφ 1H),
Image lag can increase.
Data Sheet S16614EJ2V0DS
5
µ PD8873
ELECTRICAL CHARACTERISTICS
TA = +25°C, VOD = 12 V, data rate (fφ R) = 2 MHz, storage time = 5.5 ms, input signal clock = 5 Vp-p,
light source : 3200 K halogen lamp + C-500S (infrared cut filter, t = 1 mm) + HA-50 (heat absorbing filter, t = 3 mm)
Parameter
Symbol
Min.
Typ.
Max.
Unit
Vsat
2.4
2.7
−
V
Red
SER
−
0.423
−
lx•s
Green
SEG
−
0.431
−
lx•s
Saturation voltage
Saturation exposure
Test Conditions
−
0.668
−
lx•s
Photo response non-uniformity
PRNU
VOUT = 1.0 V
−
6
20
%
Average dark signal
ADS
Light shielding
−
0.2
2.0
mV
Dark signal non-uniformity
DSNU
Light shielding
−
1.5
5.0
mV
Power consumption
PW
−
360
540
mW
Output impedance
ZO
−
0.35
1.00
kΩ
RR
4.47
6.38
8.30
V/lx•s
Blue
Response
Red
Green
RG
4.38
6.26
8.14
V/lx•s
Blue
RB
2.83
4.04
5.25
V/lx•s
−
3.0
7.0
%
Image lag
IL
Offset level
Output fall delay time
SEB
VOUT = 1.0 V
VOS
Note
Total transfer efficiency
6.0
7.0
V
VOUT = 1.0 V, t1, t2 = 25 ns
−
20
−
ns
TTE
VOUT = 1.0 V, data rate = 12.5 MHz
92
98
−
%
RI
VOUT = 1.0 V
−
1.0
4.0
%
Red
−
630
−
nm
Green
−
540
−
nm
Register imbalance
Response peak
5.0
td
−
460
−
nm
DR1
Vsat/DSNU
−
1800
−
times
DR2
Vsat/σ CDS
−
2700
−
times
Blue
Dynamic range
Reset feed-through noise
Random noise (CDS)
RFTN
Light shielding
−2000
−100
+500
mV
PRFTN
Light shielding
−
500
800
mV
σ CDS
Light shielding
−
1.0
−
mV
Note When the fall time of φ 1 and φ 2 (t1, t2) is the Typ. value (refer to TIMING CHART 2-1 to 2-3).
6
Data Sheet S16614EJ2V0DS
µ PD8873
INPUT PIN CAPACITANCE (TA = +25°C, VOD = 12 V)
Parameter
Symbol
Shift register clock pin capacitance 1
Cφ 1
Pin name
φ1
Pin No.
Min.
Typ.
Max.
Unit
5
−
370
−
pF
8
−
370
−
pF
−
370
−
pF
−
1110
−
pF
9
−
370
−
pF
15
−
370
−
pF
17
−
370
−
pF
−
1110
−
pF
14
φ 1 total capacitance
Shift register clock pin capacitance 2
Cφ 2
φ2
φ 2 total capacitance
Reset gate clock pin capacitance
Cφ R
φR
3
−
10
−
pF
Reset feed-through level clamp clock pin capacitance
Cφ CLB
φ CLB
4
−
10
−
pF
dpi select signal pin capacitance
Cφ SEL
φ SEL
19
−
10
−
pF
Transfer gate clock pin capacitance
Cφ TG
φ TG1
13
−
100
−
pF
φ TG2
12
−
100
−
pF
φ TG3
10
−
100
−
pF
Remarks 1.
2.
Pin 5, 8, 14 (φ 1) and pin 9, 15, 17 (φ 2) are each connected inside of the device.
Cφ 1 and Cφ 2 show the equivalent capacity of the real drive including the capacity of between φ 1 and
φ 2.
Data Sheet S16614EJ2V0DS
7
8
TIMING CHART 1-1 (1200 dpi, bit clamp mode, for each color)
φ TG1 to φ TG3
φ1
φ2
φR
φ CLB
10864
10865
10866
10867
10868
10869
“H”
59
60
61
62
63
64
65
φ SEL
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Data Sheet S16614EJ2V0DS
Note
Note
VOUT1 to VOUT3
Optical black
(47 pixels)
Valid photocell
(10800 pixels)
Note Set the φ R to low level and φ CLB to high level during this period.
Invalid photocell
(4 pixels)
µ PD8873
Invalid photocell
(4 pixels)
TIMING CHART 1-2 (1200 dpi, line clamp mode, for each color)
φ TG1 to φ TG3
φ1
φ2
φR
Note
φ CLB
( φ TG1 to φ TG3)
10864
10865
10866
10867
10868
10869
“H”
59
60
61
62
63
64
65
φ SEL
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Data Sheet S16614EJ2V0DS
Note
VOUT1 to VOUT3
Optical black
(47 pixels)
Valid photocell
(10800 pixels)
Note Set the φ R and φ CLB to low level during this period.
9
Remark Inverse pulse of the φ TG1 to φ TG3 can be used as φ CLB.
Invalid photocell
(4 pixels)
µ PD8873
Invalid photocell
(4 pixels)
10
TIMING CHART 1-3 (600 dpi, bit clamp mode, for each color)
φ TG1 to φ TG3
φ1
φ2
φR
Note
φ CLB
10870
10868
10866
10864
10862
68
66
64
62
60
58
16
14
12
10
8
6
“L”
4
φ SEL
2
Data Sheet S16614EJ2V0DS
Note
VOUT1 to VOUT3
Valid photocell
(5400 pixels)
Optical black
(24 pixels)
Note Set the φ R to low level and φ CLB to high level during this period.
Invalid photocell
(2 pixels)
µ PD8873
Invalid photocell
(2 pixels)
TIMING CHART 1-4 (600 dpi, line clamp mode, for each color)
φ TG1 to φ TG3
φ1
φ2
φR
Note
φ CLB
( φ TG1 to φ TG3)
10870
10868
10866
10864
10862
68
66
64
62
60
58
16
14
12
10
8
6
“L”
4
φ SEL
2
Data Sheet S16614EJ2V0DS
Note
VOUT1 to VOUT3
Valid photocell
(5400 pixels)
Optical black
(24 pixels)
Note Set the φ R and φ CLB to low level during this period.
11
Remark Inverse pulse of the φ TG1 to φ TG3 can be used as φ CLB.
Invalid photocell
(2 pixels)
µ PD8873
Invalid photocell
(2 pixels)
12
TIMING CHART 1-5 (300 dpi, bit clamp mode, for each color)
φ TG1 to φ TG3
φ1
φ2
φR
Note
φ CLB
10870
+10872
10866
+10868
10862
+10864
66
+68
62
+64
58
+60
14
+16
10
+12
“L”
6
+8
φ SEL
2
+4
Data Sheet S16614EJ2V0DS
Note
VOUT1 to VOUT3
Valid photocell
(2700 pixels)
Optical black
(12 pixels)
Note Set the φ R to low level and φ CLB to high level during this period.
Invalid photocell
(1 pixels)
µ PD8873
Invalid photocell
(1 pixels)
TIMING CHART 1-6 (300 dpi, line clamp mode, for each color)
φ TG1 to φ TG3
φ1
φ2
φR
Note
φ CLB
( φ TG1 to φ TG3)
10870
+10872
10866
+10868
10862
+10864
66
+68
62
+64
58
+60
14
+16
10
+12
“L”
6
+8
φ SEL
2
+4
Data Sheet S16614EJ2V0DS
Note
VOUT1 to VOUT3
Valid photocell
(2700 pixels)
Optical black
(12 pixels)
Note Set the φ R and φ CLB to low level during this period.
13
Remark Inverse pulse of the φ TG1 to φ TG3 can be used as φ CLB.
Invalid photocell
(1 pixels)
µ PD8873
Invalid photocell
(1 pixels)
µ PD8873
TIMING CHART 2-1 (1200 dpi, for each color)
t2
t1
φ1
90%
10%
φ2
90%
10%
φR
90%
10%
t4 t3 t5
t4 t3 t5
t6 t8 t7 t9
φ CLB
(Bit clamp mode)
φ CLB “H”
(Line clamp mode)
t6 t8 t7 t9
t10
90%
10%
t11
t12
td
td
VOUT
10%
Symbol
Min.
Typ.
Note
Max.
Unit
t1, t2
0
25
−
ns
t3
20
50
−
ns
t4, t5
0
20
−
ns
t6
15
25
−
ns
t7
10
50
−
ns
t8, t9
0
20
−
ns
t10
5
45
−
ns
t11
40
−
−
ns
t12
40
−
−
ns
Note Typ. is the case of φ R = 2 MHz.
14
t10
Data Sheet S16614EJ2V0DS
µ PD8873
TIMING CHART 2-2 (600 dpi, for each color)
t2
φ1
90%
10%
φ2
90%
10%
φR
90%
10%
t1
t4 t3 t5
t6 t8 t7 t9
φ CLB
(Bit clamp mode)
φ CLB “H”
(Line clamp mode)
t10
90%
10%
t11
t12
td
VOUT
10%
Symbol
Min.
Typ.
Note
Max.
Unit
t1, t2
0
25
−
ns
t3
20
50
−
ns
t4, t5
0
20
−
ns
t6
15
25
−
ns
t7
10
50
−
ns
t8, t9
0
20
−
ns
t10
5
45
−
ns
t11
40
−
−
ns
t12
40
−
−
ns
Note Typ. is the case of φ R = 2 MHz.
Data Sheet S16614EJ2V0DS
15
µ PD8873
TIMING CHART 2-3 (300 dpi, for each color)
t2
φ1
90%
10%
φ2
90%
10%
φR
90%
10%
t1
t3
t4 t5
t6
φ CLB
(Bit clamp mode)
φ CLB “H”
(Line clamp mode)
t8
t7
t9
t10
90%
10%
t11
t12
td
VOUT
10%
Symbol
Min.
Typ.
Note
Unit
t1, t2
0
25
−
ns
t3
20
50
−
ns
t4, t5
0
20
−
ns
t6
15
25
−
ns
t7
10
50
−
ns
t8, t9
0
20
−
ns
t10
5
45
−
ns
t11
40
−
−
ns
t12
40
−
−
ns
Note Typ. is the case of φ R = 1 MHz.
16
Max.
Data Sheet S16614EJ2V0DS
µ PD8873
φ TG1 to φ TG3, φ 1, φ 2 TIMING CHART
t14
t15
t13
90%
10%
t16
φ TG1 to φ TG3
t17
90%
φ1
φ2
t18
φR
Note 1
t19
10%
t6
90%
φ CLB
(Bit clamp mode)
t21
t23
t22
Note 2
t24
90%
10%
φ CLB
(Line clamp mode)
t8
Symbol
t6
t20
t9
Min.
Typ.
Max.
Unit
15
25
−
ns
0
20
−
ns
5000
10000
50000
ns
t14, t15
0
50
−
ns
t16, t17
900
1000
−
ns
t18, t19
200
400
−
ns
t20
t8, t9
t13
t13
t13
50000
ns
t21, t22
0
50
−
ns
t23
t6
t6
−
ns
t24
0
350
−
ns
Notes 1. Set the φ R to low level and φ CLB to high level during this period.
2. Set the φ R to low level during this period.
Remark Inverse pulse of the φ TG1 to φ TG3 can be used as φ CLB.
Data Sheet S16614EJ2V0DS
17
µ PD8873
φ 1, φ 2 CROSS POINTS
t25
t27
φ1
φ2
0.25 V
1.5 V to 3.5 V
t26
Min.
Typ.
Max.
Unit
t25
Symbol
80
−
−
ns
t26, t27
35
−
−
ns
φ TG, φ SEL TIMING CHART
90%
φ TG
t28
φ SEL (High to Low)
90%
10%
φ SEL (Low to High)
Symbol
t28
18
Min.
Typ.
Max.
Unit
0
0
−
ns
Data Sheet S16614EJ2V0DS
4.75 V
µ PD8873
SELECTION OF RESOLUTION MODE
The µ PD8873 has function of two readout modes, High Resolution Mode and Low Resolution Mode. These two
modes can be selected by φ SEL switch.
Read Mode
φ SEL
Description
High Resolution Mode
1200 dpi (Max.)
High level
Low Resolution Mode
600 dpi (Max.) (even line readout mode)
Low level
(1) High Resolution Mode
In this mode, both signals in even lines and odd lines can be read out. This mode enables 1200 dpi (Max.)
resolution with A4 size (210 × 297 mm, shorter side).
Please refer to TIMING CHART 1-1, 1-2 and 2-1.
(2) Low Resolution Mode
In this mode, only signal in even lines can be read out.
This mode enables 600 dpi (Max.) resolution with A4 size.
To use intermittent reset drive enable signal charges of adjacent pixels in even line to add at the charge to voltage
conversion area. Then it can achieve low resolution with A4 size such as 300, 200 or 150 dpi.
Please refer to TIMING CHART 1-3 to 1-6, 2-2 and 2-3.
Data Sheet S16614EJ2V0DS
19
µ PD8873
DEFINITIONS OF CHARACTERISTIC ITEMS
1. Saturation voltage : Vsat
Output signal voltage at which the response linearity is lost.
2. Saturation exposure : SE
Product of intensity of illumination (lx) and storage time (s) when saturation of output voltage occurs.
3. Photo response non-uniformity : PRNU
The output signal non-uniformity of all the valid pixels when the photosensitive surface is applied with the light
of uniform illumination. This is calculated by the following formula.
PRNU (%) =
∆x
× 100
x
∆ x : maximum of xj − x 
10800
Σx
j
x=
j=1
10800
xj : Output voltage of valid pixel number j
VOUT
Register Dark
DC level
x
∆x
4. Average dark signal : ADS
Average output signal voltage of all the valid pixels at light shielding. This is calculated by the following
formula.
10800
Σd
j
ADS (mV) =
j=1
10800
dj : Dark signal of valid pixel number j
20
Data Sheet S16614EJ2V0DS
µ PD8873
5. Dark signal non-uniformity : DSNU
Absolute maximum of the difference between ADS and voltage of the highest or lowest output pixel of all the
valid pixels at light shielding. This is calculated by the following formula.
DSNU (mV) : maximum of dj − ADS j = 1 to 10800
dj : Dark signal of valid pixel number j
VOUT
ADS
Register Dark
DC level
DSNU
6. Output impedance : ZO
Impedance of the output pins viewed from outside.
7. Response : R
Output voltage divided by exposure (lx•s).
Note that the response varies with a light source (spectral characteristic).
8. Image lag : IL
The rate between the last output voltage and the next one after read out the data of a line.
φ TG
Light
ON
OFF
VOUT
V1
VOUT
IL (%) =
V1
× 100
VOUT
Data Sheet S16614EJ2V0DS
21
µ PD8873
9. Register imbalance: RI
The rate of the difference between the averages of the output voltage of Odd and Even pixels, against the
average output voltage of all the valid pixels.
n
2
2
n
∑ (V2j –1 – V2j)
j=1
RI (%) =
n
1
n
× 100
∑ Vj
j=1
n : Number of valid pixels
Vj : Output voltage of each pixel
10. Offset level : VOS
DC level of output signal is defined as follows.
11. Reset feed-through noise : RFTN, PRFTN
Reset feed-through noise (RFTN) and peak of RFTN (PRFTN) are defined as follows.
+
PRFTN
VOUT
22
PRFTN
–
RFTN
VOS
Data Sheet S16614EJ2V0DS
µ PD8873
12. Random noise (CDS) : σ CDS
Random noise σ CDS is defined as the standard deviation of a valid pixel output signal with 100 times (=100
lines) data sampling at dark (light shielding). σ CDS is calculated by the following procedure.
1. One valid photocell in one reading is fixed as measurement point.
2. The output level is measured during the reset feed-through period which is averaged over 100 ns to get
“VDi”.
3. The output level is measured during the video output time averaged over 100 ns to get “VOi”.
4. The correlated double sampling output is defined by the following formula.
VCDSi = VDi – VOi
5. Repeat the above procedure (1 to 4) for 100 times (= 100 lines).
6. Calculate the standard deviation σ CDS using the following formula equation.
100
σ CDS (mV) =
Σ (VCDS – V)
i
2
i=1
100
, V=
1
100
Σ VCDS
i
100 i = 1
Reset feed-through
Video output
Data Sheet S16614EJ2V0DS
23
µ PD8873
STANDARD CHARACTERISTIC CURVES (Reference Value)
DARK OUTPUT TEMPERATURE
CHARACTERISTIC
STORAGE TIME OUTPUT VOLTAGE
CHARACTERISTIC (TA = +25°C)
8
2
1
Relative Output Voltage
Relative Output Voltage
4
2
1
0.5
0.2
0.25
0.1
0
10
20
30
40
0.1
50
Operating Ambient Temperature TA (°C)
1
5
10
Storage Time (ms)
TOTAL SPECTRAL RESPONSE CHARACTERISTICS
(without infrared cut filter and heat absorbing filter) (TA = +25°C)
100
R
B
G
Response Ratio (%)
80
60
40
G
20
B
0
400
500
600
Wavelength (nm)
24
Data Sheet S16614EJ2V0DS
700
800
µ PD8873
APPLICATION CIRCUIT EXAMPLE
+12 V
+5 V
+
+
µ PD8873
10 µ F/16 V 0.1 µ F
B3
1
2
φR
φ CLB
47 Ω
3
47 Ω
4
4.7 Ω
5
6
7
4.7 Ω
8
4.7 Ω
9
φ2
10 Ω
10
11
VOUT3
VOUT2
VOUT1
GND
φR
VOD
φ SEL
φ CLB
φ1
NC
NC
φ2
NC
NC
φ1
φ2
φ2
φ1
φ TG3
φ TG1
φ TG2
GND
22
21
B2
0.1 µ F 47 µ F/25 V
+5 V
B1
20
+
19 150 Ω
0.1 µ F 10 µ F/16 V
18
17
φ SEL
4.7 Ω
16
15
4.7 Ω
14
4.7 Ω
13
10 Ω
12
10 Ω
φ1
φ TG
Caution Connect the No connection pins (NC) to GND.
Remarks 1. The inverters shown in the above application circuit example are the 74HC04 (fφ R < 2 MHz) or the
74AC04 (2 MHz ≤ fφ R ≤ 12.5 MHz).
2. Inverters B1 to B3 in the above application circuit example are shown in the figure below.
B1 to B3 EQUIVALENT CIRCUIT
12 V
+
100 Ω
CCD
VOUT
100 Ω
47 µ F/25 V
2SC945
2 kΩ
Data Sheet S16614EJ2V0DS
25
µ PD8873
PACKAGE DRAWING
µ PD8873CY
CCD LINEAR IMAGE SENSOR 22-PIN PLASTIC DIP (10.16 mm (400))
(Unit : mm)
44.0±0.3
1st valid pixel
0.5±0.3
1
9.25±0.3
12
22
11
1
37.5
4
1.02±0.15
0.46±0.1
2.0
4.39±0.4
2.54±0.25
(5.42)
4
(1.72)
2
2.62±0.2
3
10.16±0.2
0.25±0.05
10.16 +0.7
−0.2
4.21±0.5
Name
Plastic cap
Dimensions
Refractive index
42.7×8.35×0.8(0.7 5)
1.5
1 1st valid pixel
The center of the pin1
2 The surface of the CCD chip
The top of the cap
3 The bottom of the package
The surface of the CCD chip
4 Mirror finished surface
5 Thickness of mirror finished surface
22C-1CCD-PKG17
26
Data Sheet S16614EJ2V0DS
µ PD8873
RECOMMENDED SOLDERING CONDITIONS
When soldering this product, it is highly recommended to observe the conditions as shown below.
If other soldering processes are used, or if the soldering is performed under different conditions, please make sure
to consult with our sales offices.
Type of Through-hole Device
µ PD8873CY : CCD linear image sensor 22-pin plastic DIP (10.16 mm (400))
Process
Partial heating method
Cautions 1.
Conditions
Pin temperature : 300 °C or below, Heat time : 3 seconds or less (per pin)
During assembly care should be taken to prevent solder or flux from contacting the plastic
cap. The optical characteristics could be degraded by such contact.
2.
Soldering by the solder flow method may have deleterious effects on prevention of plastic
cap soiling and heat resistance. So the method cannot be guaranteed.
Data Sheet S16614EJ2V0DS
27
µ PD8873
NOTES ON HANDLING THE PACKAGES
1 DUST AND DIRT PROTECTING
The optical characteristics of the CCD will be degraded if the cap is scratched during cleaning. Don’t either
touch plastic cap surface by hand or have any object come in contact with plastic cap surface. Should dirt
stick to a plastic cap surface, blow it off with an air blower. For dirt stuck through electricity ionized air is
recommended. And if the plastic cap surface is grease stained, clean with our recommended solvents.
CLEANING THE PLASTIC CAP
Care should be taken when cleaning the surface to prevent scratches.
We recommend cleaning the cap with a soft cloth moistened with one of the recommended solvents below.
Excessive pressure should not be applied to the cap during cleaning. If the cap requires multiple cleanings it is
recommended that a clean surface or cloth be used.
RECOMMENDED SOLVENTS
The following are the recommended solvents for cleaning the CCD plastic cap.
Use of solvents other than these could result in optical or physical degradation in the plastic cap.
Please consult your sales office when considering an alternative solvent.
Solvents
Ethyl Alcohol
Methyl Alcohol
Isopropyl Alcohol
N-methyl Pyrrolidone
Symbol
EtOH
MeOH
IPA
NMP
2 MOUNTING OF THE PACKAGE
The application of an excessive load to the package may cause the package to warp or break, or cause chips
to come off internally. Particular care should be taken when mounting the package on the circuit board. Don't
have any object come in contact with plastic cap. You should not reform the lead frame. We recommended to
use a IC-inserter when you assemble to PCB.
Also, be care that the any of the following can cause the package to crack or dust to be generated.
1. Applying heat to the external leads for an extended period of time with soldering iron.
2. Applying repetitive bending stress to the external leads.
3. Rapid cooling or heating
3 OPERATE AND STORAGE ENVIRONMENTS
Operate in clean environments. CCD image sensors are precise optical equipment that should not be subject
to mechanical shocks. Exposure to high temperatures or humidity will affect the characteristics. So avoid
storage or usage in such conditions.
Keep in a case to protect from dust and dirt. Dew condensation may occur on CCD image sensors when the
devices are transported from a low-temperature environment to a high-temperature environment. Avoid such
rapid temperature changes.
For more details, refer to our document "Review of Quality and Reliability Handbook" (C12769E)
4 ELECTROSTATIC BREAKDOWN
CCD image sensor is protected against static electricity, but destruction due to static electricity is sometimes
detected. Before handling be sure to take the following protective measures.
1.
2.
3.
4.
5.
6.
28
Ground the tools such as soldering iron, radio cutting pliers of or pincer.
Install a conductive mat or on the floor or working table to prevent the generation of static electricity.
Either handle bare handed or use non-chargeable gloves, clothes or material.
Ionized air is recommended for discharge when handling CCD image sensor.
For the shipment of mounted substrates, use box treated for prevention of static charges.
Anyone who is handling CCD image sensors, mounting them on PCBs or testing or inspecting PCBs on
which CCD image sensors have been mounted must wear anti-static bands such as wrist straps and ankle
straps which are grounded via a series resistance connection of about 1 MΩ.
Data Sheet S16614EJ2V0DS
µ PD8873
[MEMO]
Data Sheet S16614EJ2V0DS
29
µ PD8873
[MEMO]
30
Data Sheet S16614EJ2V0DS
µ PD8873
NOTES FOR CMOS DEVICES
1
PRECAUTION AGAINST ESD FOR SEMICONDUCTORS
Note:
Strong electric field, when exposed to a MOS device, can cause destruction of the gate oxide and
ultimately degrade the device operation. Steps must be taken to stop generation of static electricity
as much as possible, and quickly dissipate it once, when it has occurred. Environmental control
must be adequate. When it is dry, humidifier should be used. It is recommended to avoid using
insulators that easily build static electricity. Semiconductor devices must be stored and transported
in an anti-static container, static shielding bag or conductive material. All test and measurement
tools including work bench and floor should be grounded. The operator should be grounded using
wrist strap. Semiconductor devices must not be touched with bare hands. Similar precautions need
to be taken for PW boards with semiconductor devices on it.
2
HANDLING OF UNUSED INPUT PINS FOR CMOS
Note:
No connection for CMOS device inputs can be cause of malfunction. If no connection is provided
to the input pins, it is possible that an internal input level may be generated due to noise, etc., hence
causing malfunction. CMOS devices behave differently than Bipolar or NMOS devices. Input levels
of CMOS devices must be fixed high or low by using a pull-up or pull-down circuitry. Each unused
pin should be connected to V DD or GND with a resistor, if it is considered to have a possibility of
being an output pin. All handling related to the unused pins must be judged device by device and
related specifications governing the devices.
3
STATUS BEFORE INITIALIZATION OF MOS DEVICES
Note:
Power-on does not necessarily define initial status of MOS device. Production process of MOS
does not define the initial operation status of the device. Immediately after the power source is
turned ON, the devices with reset function have not yet been initialized. Hence, power-on does
not guarantee out-pin levels, I/O settings or contents of registers. Device is not initialized until the
reset signal is received. Reset operation must be executed immediately after power-on for devices
having reset function.
Data Sheet S16614EJ2V0DS
31
µ PD8873
• The information in this document is current as of July, 2003. The information is subject to change
without notice. For actual design-in, refer to the latest publications of NEC Electronics data sheets or
data books, etc., for the most up-to-date specifications of NEC Electronics products. Not all
products and/or types are available in every country. Please check with an NEC Electronics sales
representative for availability and additional information.
• No part of this document may be copied or reproduced in any form or by any means without the prior
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• Descriptions of circuits, software and other related information in this document are provided for illustrative
purposes in semiconductor product operation and application examples. The incorporation of these
circuits, software and information in the design of a customer's equipment shall be done under the full
responsibility of the customer. NEC Electronics assumes no responsibility for any losses incurred by
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The "Specific" quality grade applies only to NEC Electronics products developed based on a customerdesignated "quality assurance program" for a specific application. The recommended applications of an NEC
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The quality grade of NEC Electronics products is "Standard" unless otherwise expressly specified in NEC
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(Note)
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defined above).
M8E 02. 11-1