© Semiconductor Components Industries, LLC, 2015
April, 2015 − Rev. 6 1Publication Order Number:
KAI−02150/D
KAI-02150
1920 (H) x 1080 (V) Interline
CCD Image Sensor
Description
The KAI−02150 Image Sensor is a 1080p (1920 × 1080) CCD in
a 2/3″ optical format. Based on the TRUESENSE 5.5-micron Interline
Transfer CCD Platform, the sensor features broad dynamic range,
excellent imaging performance, and a flexible readout architecture
that enables use of 1, 2, or 4 outputs for full resolution readout up to
64 frames per second. A vertical overflow drain structure suppresses
image blooming and enables electronic shuttering for precise exposure
control.
Table 1. GENERAL SPECIFICATIONS
Parameter Typical Value
Architecture Interline CCD, Progressive Scan
Total Number of Pixels 2004 (H) × 1144 (V)
Number of Effective Pixels 1960 (H) × 1120 (V)
Number of Active Pixels 1920 (H) × 1080 (V)
Pixel Size 5.5 mm (H) × 5.5 mm (V)
Active Image Size 10.56 mm (H) × 5.94 mm (V)
12.1 mm (Diagonal),
2/3″ Optical Format
Aspect Ratio 16:9
Number of Outputs 1, 2, or 4
Charge Capacity 20,000 electrons
Output Sensitivity 34 mV/e−
Quantum Efficiency
Pan (−ABA, −PBA)
R, G, B (−FBA, −QBA)
R, G, B (−CBA, −PBA)
44%
31%, 37%, 38%
29%, 37%, 39%
Base ISO
KAI−02150−ABA
KAI−02150−FBA
KAI−02150−CBA
KAI−02150−PBA
330
170
150
330
Read Noise (f = 40 MHz) 12 e− rms
Dark Current
Photodiode/VCCD 7/100 e−/s
Dark Current Doubling Temp
Photodiode/VCCD 7°C/9°C
Dynamic Range 64 dB
Charge Transfer Efficiency 0.999999
Blooming Suppression > 300 X
Smear −100 dB
Image Lag < 10 electrons
Maximum Pixel Clock Speed 40 MHz
Maximum Frame Rate
Quad/Dual/Single Output 64/33/17 fps
Package 68 Pin PGA
64 Pin CLCC
Cover Glass AR Coated, 2-Sides or Clear Glass
NOTE: All Parameters are specified at T = 40°C unless otherwise noted.
Features
•Bayer Color Pattern, TRUESENSE Sparse
Color Filter Pattern, and Monochrome
Configurations
•Progressive Scan Readout
•Flexible Readout Architecture
•High Frame Rate
•High Sensitivity
•Low Noise Architecture
•Excellent Smear Performance
•Package Pin Reserved for Device
Identification
Applications
•Industrial Imaging
•Medical Imaging
•Security
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Figure 1. KAI−02150 Interline CCD
Image Sensor
See detailed ordering and shipping information on page 2 o
f
this data sheet.
ORDERING INFORMATION
KAI−02150
www.onsemi.com
2
The sensor is available with the TRUESENSE Sparse
Color Filter Pattern, a technology which provides a 2x
improvement in light sensitivity compared to a standard
color Bayer part.
The sensor shares common PGA pin-out and electrical
configurations with other devices based on the
TRUESENSE 5. 5 micron Interline Transfer CCD Platform,
allowing a single camera design to support multiple
members of this sensor family.
ORDERING INFORMATION
Standard Devices
See full datasheet for ordering information associated
with devices no longer recommended for new designs.
Table 2. ORDERING INFORMATION − STANDARD DEVICES
Part Number Description Marking Code
KAI−02150−AAA−JP−BA Monochrome, No Microlens, PGA Package, Taped Clear Cover Glass, No
Coatings, Standard Grade. KAI−02150−AAA
Serial Number
KAI−02150−AAA−JP−AE Monochrome, No Microlens, PGA Package, Taped Clear Cover Glass, No
Coatings, Engineering Grade.
KAI−02150−ABA−JD−BA Monochrome, Telecentric Microlens, PGA Package, Sealed Clear Cover Glass
with AR Coating (Both Sides), Standard Grade.
KAI−02150−ABA
Serial Number
KAI−02150−ABA−JD−AE Monochrome, Telecentric Microlens, PGA Package, Sealed Clear Cover Glass
with AR Coating (Both Sides), Engineering Grade.
KAI−02150−ABA−JP−BA Monochrome, Telecentric Microlens, PGA Package, Taped Clear Cover Glass,
No Coatings, Standard Grade.
KAI−02150−ABA−JP−AE Monochrome, Telecentric Microlens, PGA Package, Taped Clear Cover Glass,
No Coatings, Engineering Grade.
KAI−02150−ABA−FD−BA Monochrome, Telecentric Microlens, CLCC Package, Sealed Clear Cover Glass
with AR Coating (Both Sides), Standard Grade.
KAI−02150−ABA−FD−AE Monochrome, Telecentric Microlens, CLCC Package, Sealed Clear Cover Glass
with AR Coating (Both Sides), Engineering Grade.
KAI−02150−FBA−JD−BA Gen2 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−FBA
Serial Number
KAI−02150−FBA−JD−AE Gen2 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Engineering Grade.
KAI−02150−FBA−FD−BA Gen2 Color (Bayer RGB), Telecentric Microlens, CLCC Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−FBA−FD−AE Gen2 Color (Bayer RGB), Telecentric Microlens, CLCC Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Engineering Grade.
KAI−02150−FBA−JB−B2 Gen2 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass (No Coatings), Grade 2. KAI−02150−FBA
Serial Number
VAB = xx.x
KAI−02150−FBA−JB−AE Gen2 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass (No Coatings), Engineering Grade.
KAI−02150−FBA−JB−B2−T Gen2 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass (No Coatings), Grade 2, Packed in Trays.
KAI−02150−QBA−JD−BA Gen2 Color (TRUESENSE Sparse CFA), Telecentric Microlens, PGA Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−QBA
Serial Number
KAI−02150−QBA−JD−AE Gen2 Color (TRUESENSE Sparse CFA), Telecentric Microlens, PGA Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Engineering Grade.
KAI−02150−QBA−FD−BA Gen2 Color (TRUESENSE Sparse CFA), Telecentric Microlens, CLCC Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−QBA−FD−AE Gen2 Color (TRUESENSE Sparse CFA), Telecentric Microlens, CLCC Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Engineering Grade.
See the ON Semiconductor Device Nomenclature document (TND310/D) for a full description of the naming convention
used for image sensors. For reference documentation, including information on evaluation kits, please visit our web site at
www.onsemi.com.
KAI−02150
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3
Not Recommended for New Designs
Table 3. ORDERING INFORMATION − NOT RECOMMENDED FOR NEW DESIGNS
Part Number Description Marking Code
KAI−02150−CBA−JD−BA Gen1 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−CBA
Serial Number
KAI−02150−CBA−JD−AE Gen1 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Engineering Grade.
KAI−02150−CBA−FD−BA Gen1 Color (Bayer RGB), Telecentric Microlens, CLCC Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−CBA−FD−AE Gen1 Color (Bayer RGB), Telecentric Microlens, CLCC Package, Sealed Clear
Cover Glass with AR Coating (Both Sides), Engineering Grade.
KAI−02150−CBA−JB−B2 Gen1 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass (No Coatings), Grade 2. KAI−02150−CBA
Serial Number
VAB = xx.x
KAI−02150−CBA−JB−AE Gen1 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass (No Coatings), Engineering Grade.
KAI−02150−CBA−JB−B2−T Gen1 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear
Cover Glass (No Coatings), Grade 2, Packed in Trays.
KAI−02150−PBA−JD−BA Gen1 Color (TRUESENSE Sparse CFA), Telecentric Microlens, PGA Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−PBA
Serial Number
KAI−02150−PBA−JD−AE Gen1 Color (TRUESENSE Sparse CFA), Telecentric Microlens, PGA Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Engineering Grade.
KAI−02150−PBA−FD−BA Gen1 Color (TRUESENSE Sparse CFA), Telecentric Microlens, CLCC Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Standard Grade.
KAI−02150−PBA−FD−AE Gen1 Color (TRUESENSE Sparse CFA), Telecentric Microlens, CLCC Package,
Sealed Clear Cover Glass with AR Coating (Both Sides), Engineering Grade.
KAI−02150
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4
DEVICE DESCRIPTION
Architecture
Figure 2. Block Diagram
22
12 Dark
12
20
V1B
20 Buffer
20
20
22
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
1 Dummy
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
1 Dummy
960 960
960 960
V2B
V3B
V4B
V1T
V2T
V3T
V4T
H1Sa
H1Ba
H2Sa
H2Ba
RDa
Ra
VDDa
VOUTa
GND
H1Sb
H1Bb
H2Sb
H2Bb
RDc
Rc
VDDc
VOUTc
GND
RDd
Rd
VDDd
VOUTd
GND
RDb
Rb
VDDb
VOUTb
GND
V1B
V2B
V3B
V4B
V1T
V2T
V3T
V4T
H1Sd
H1Bd
H2Sd
H2Bd
H1Sc
H1Bc
H2Sc
H2Bc
H2SLa
OGa
H2SLc
OGc H2SLd
OGd
H2SLb
OGb
ESD ESD
SUBSUB
122 2010 12220 10
122 2010 12220 10
DevID
1920 (H) × 1080 (V)
5.5 mm × 5.5 mm Pixels
(Last VCCD Phase = V1 → H1S)
Dark Reference Pixels
There are 12 dark reference rows at the top and 12 dark
rows a t the bottom of the image sensor. The dark rows are not
entirely dark and so should not be used for a dark reference
level. Use the 22 dark columns on the left or right side of the
image sensor as a dark reference.
Under normal circumstances use only the center 20
columns of the 22 column dark reference due to potential
light leakage.
Dummy Pixels
Within each horizontal shift register there are 11 leading
additional shift phases. These pixels are designated as
dummy pixels and should not be used to determine a dark
reference level.
In addition, there is one dummy row of pixels at the top
and bottom of the image.
Active Buffer Pixels
20 unshielded pixels adjacent to any leading or trailing
dark reference regions are classified as active buffer pixels.
These pixels are light sensitive but are not tested for defects
and non-uniformities.
Image Acquisition
An electronic representation of an image is formed when
incident photons falling on the sensor plane create
electron-hole pairs within the individual silicon
photodiodes. These photoelectrons are collected locally by
the formation of potential wells at each photosite. Below
photodiode saturation, the number of photoelectrons
collected at each pixel is linearly dependent upon light level
and exposure time and non-linearly dependent on
wavelength. When the photodiodes charge capacity is
reached, excess electrons are discharged into the substrate to
prevent blooming.
ESD Protection
Adherence to the power -up and power-down sequence is
critical. Failure to follow the proper power-up and
power-down sequences may cause damage to the sensor. See
Power -Up and Power-Down Sequence section.
KAI−02150
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5
Bayer Color Filter Pattern
Figure 3. Bayer Color Filter Pattern
22
12 Dark
12
20
V1B
20 Buffer
20
20
22
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
1 Dummy
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
1 Dummy
960 960
960 960
V2B
V3B
V4B
V1T
V2T
V3T
V4T
H1Sa
H1Ba
H2Sa
H2Ba
RDa
Ra
VDDa
VOUTa
GND
H1Sb
H1Bb
H2Sb
H2Bb
RDc
Rc
VDDc
VOUTc
GND
RDd
Rd
VDDd
VOUTd
GND
RDb
Rb
VDDb
VOUTb
GND
V1B
V2B
V3B
V4B
V1T
V2T
V3T
V4T
H
1Sd
H
1Bd
H
2Sd
H
2Bd
H
1Sc
H
1Bc
H
2Sc
H
2Bc
H2SLa
OGa
H2SLc
OGc H2SLd
OGd
H2SLb
OGb
ESD ESD
SUB
S
UB
122 2010 12220 10
122 2010 12220 10
DevID
1920 (H) × 1080 (V)
5.5 mm × 5.5 mm Pixels
(Last VCCD Phase = V1 → H1S)
G
B
GR
G
B
GR
G
B
GR
G
B
GR
TRUESENSE Sparse Color Filter Pattern
Figure 4. TRUESENSE Sparse Color Filter Pattern
22
12 Dark
12
20
V1B
20 Buffer
20
20
22
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
1 Dummy
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ
1 Dummy
960 960
960 960
V2B
V3B
V4B
V1T
V2T
V3T
V4T
H1Sa
H1Ba
H2Sa
H2Ba
RDa
Ra
VDDa
VOUTa
GND
H1Sb
H1Bb
H2Sb
H2Bb
RDc
Rc
VDDc
VOUTc
GND
RDd
Rd
VDDd
VOUTd
GND
RDb
Rb
VDDb
VOUTb
GND
V1B
V2B
V3B
V4B
V1T
V2T
V3T
V4T
H
1Sd
H
1Bd
H
2Sd
H
2Bd
H
1Sc
H
1Bc
H
2Sc
H
2Bc
H2SLa
OGa
H2SLc
OGc H2SLd
OGd
H2SLb
OGb
ESD ESD
SUB
S
UB
122 2010 12220 10
122 2010 12220 10
DevID
1920 (H) × 1080 (V)
5.5 mm × 5.5 mm Pixels
(Last VCCD Phase = V1 → H1S)
P
G
PGP
R
PR
P
B
PBP
G
PG
P
G
PGP
R
PR
P
B
PBP
G
PG
P
G
PGP
R
PR
P
B
PBP
G
PG
P
G
PGP
R
PR
P
B
PBP
G
PG
KAI−02150
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6
Physical Description
Pin Grid Array Pin Description
Figure 5. PGA Package Pin Designations − Top View
Pixel (1, 1)
1 3 5 7 9 11 13 15 17 19 21
V3B V1B
V4B
VDDa
V2B
GND
VOUTa
Ra
RDa
H2SLa
OGa
H1Bb
H2Bb
H2Sb
H1Sb
N/C
SUB
H2Sa
H1Sa
H1Ba
H2Ba
23
H2SLb
OGb
25 27 29 31
V1B
V4B
VDDb
V2B
GND
VOUTb
Rb
RDb
33
V3B
ESD
65 63 61 59 57 55 53 51 49 47
ESD V4T
V1T
V2T
VDDc
VOUTc
GND
RDc
Rc
OGc
H2SLc
H2Bd
H1Bd
H1Sd
H2Sd
SUB
N/C
H1Sc
H2Sc
H2Bc
H1Bc
45
OGd
H2SLd
43 41 39 37
V4T
V1T
V2T
VDDd
VOUTd
GND
RDd
Rd
35
DevID
V3T
67
V3T
68 66 64 62 60 58 56 54 52 50 48 46 44 42 40 38 36
4 6 10 12 14 16 18 20 22 24 26 30 32 34
828
Table 4. PGA PACKAGE PIN DESCRIPTION
Pin Name Description
1 V3B Vertical CCD Clock, Phase 3, Bottom
3 V1B Vertical CCD Clock, Phase 1, Bottom
4 V4B Vertical CCD Clock, Phase 4, Bottom
5 VDDa Output Amplifier Supply, Quadrant a
6 V2B Vertical CCD Clock, Phase 2, Bottom
7 GND Ground
8 VOUTa Video Output, Quadrant a
9 Ra Reset Gate, Quadrant a
10 RDa Reset Drain, Quadrant a
11 H2SLa Horizontal CCD Clock, Phase 2, Storage, Last Phase, Quadrant a
12 OGa Output Gate, Quadrant a
13 H1Ba Horizontal CCD Clock, Phase 1, Barrier, Quadrant a
14 H2Ba Horizontal CCD Clock, Phase 2, Barrier, Quadrant a
15 H2Sa Horizontal CCD Clock, Phase 2, Storage, Quadrant a
16 H1Sa Horizontal CCD Clock, Phase 1, Storage, Quadrant a
17 N/C No Connect
18 SUB Substrate
19 H2Sb Horizontal CCD Clock, Phase 2, Storage, Quadrant b
20 H1Sb Horizontal CCD Clock, Phase 1, Storage, Quadrant b
21 H1Bb Horizontal CCD Clock, Phase 1, Barrier, Quadrant b
22 H2Bb Horizontal CCD Clock, Phase 2, Barrier, Quadrant b
23 H2SLb Horizontal CCD Clock, Phase 1, Storage, Last Phase, Quadrant b
24 OGb Output Gate, Quadrant b
KAI−02150
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7
Table 4. PGA PACKAGE PIN DESCRIPTION (continued)
Pin Name Description
25 Rb Reset Gate, Quadrant b
26 RDb Reset Drain, Quadrant b
27 GND Ground
28 VOUTb Video Output, Quadrant b
29 VDDb Output Amplifier Supply, Quadrant b
30 V2B Vertical CCD Clock, Phase 2, Bottom
31 V1B Vertical CCD Clock, Phase 1, Bottom
32 V4B Vertical CCD Clock, Phase 4, Bottom
33 V3B Vertical CCD Clock, Phase 3, Bottom
34 ESD ESD Protection Disable
35 V3T Vertical CCD Clock, Phase 3, Top
36 DevID Device Identification
37 V1T Vertical CCD Clock, Phase 1, Top
38 V4T Vertical CCD Clock, Phase 4, Top
39 VDDd Output Amplifier Supply, Quadrant d
40 V2T Vertical CCD Clock, Phase 2, Top
41 GND Ground
42 VOUTd Video Output, Quadrant d
43 Rd Reset Gate, Quadrant d
44 RDd Reset Drain, Quadrant d
45 H2SLd Horizontal CCD Clock, Phase 2, Storage, Last Phase, Quadrant d
46 OGd Output Gate, Quadrant d
47 H1Bd Horizontal CCD Clock, Phase 1, Barrier, Quadrant d
48 H2Bd Horizontal CCD Clock, Phase 2, Barrier, Quadrant d
49 H2Sd Horizontal CCD Clock, Phase 2, Storage, Quadrant d
50 H1Sd Horizontal CCD Clock, Phase 1, Storage, Quadrant d
51 N/C No Connect
52 SUB Substrate
53 H2Sc Horizontal CCD Clock, Phase 2, Storage, Quadrant c
54 H1Sc Horizontal CCD Clock, Phase 1, Storage, Quadrant c
55 H1Bc Horizontal CCD Clock, Phase 1, Barrier, Quadrant c
56 H2Bc Horizontal CCD Clock, Phase 2, Barrier, Quadrant c
57 H2SLc Horizontal CCD Clock, Phase 2, Storage, Last Phase, Quadrant c
58 OGc Output Gate, Quadrant c
59 Rc Reset Gate, Quadrant c
60 RDc Reset Drain, Quadrant c
61 GND Ground
62 VOUTc Video Output, Quadrant c
63 VDDc Output Amplifier Supply, Quadrant c
64 V2T Vertical CCD Clock, Phase 2, Top
65 V1T Vertical CCD Clock, Phase 1, Top
66 V4T Vertical CCD Clock, Phase 4, Top
67 V3T Vertical CCD Clock, Phase 3, Top
68 ESD EDS Protection Disable
1. Liked named pins are internally connected and should have a common drive signal.
2. N/C pins (17, 51) should be left floating.
KAI−02150
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Ceramic Leadless Chip Carrier Pin Description
Figure 6. CLCC Package Pin Designations − Top View
116
1764
32
3348
49
8
24
40
56
RDa
Ra
OGa
H2Ba
H1Ba
H1Sa
H2Sa
SUB
H2Sb
H1Sb
H1Bb
H2Bb
H2SLb
OGb
Rb
RDb
GND
VOUTb
VDDb
V2B
V1B
V4B
V3B
DevID
V3T
V4T
V1T
V2T
VDDd
VOUTd
GND
RDd
Rd
OGd
H2SL
d
H2Bd
H1Bd
H1Sd
SUB
H2Sd
H1Sc
H1Bc
H2Bc
H2SL
c
H2Sc
OGc
Rc
RDc
GND
VOUTc
VDDc
V2T
V1T
V4T
V3T
ESD
V3B
V4B
V1B
V2B
VDDa
VOUTa
GND 234567 9
18
19
20
21
22
23
25
26
27
28
29
30
31
34353637383941424344454647
50
51
52
53
54
55
57
58
59
60
61
62
63
10 11 12 13 14 15
H2SLa
Pixel (1, 1)
Table 5. CLCC PACKAGE PIN DESCRIPTION
Pin Name Description
1 RDa Reset Drain, Quadrant a
2 Ra Reset Gate, Quadrant a
3 OGa Output Gate, Quadrant a
4 H2SLa Horizontal CCD Clock, Phase 2, Storage, Last Phase, Quadrant a
5 H2Ba Horizontal CCD Clock, Phase 2, Barrier, Quadrant a
6 H1Ba Horizontal CCD Clock, Phase 1, Barrier, Quadrant a
7 H1Sa Horizontal CCD Clock, Phase 1, Storage, Quadrant a
8 H2Sa Horizontal CCD Clock, Phase 2, Storage, Quadrant a
9 SUB Substrate
10 H2Sb Horizontal CCD Clock, Phase 2, Storage, Quadrant b
11 H1Sb Horizontal CCD Clock, Phase 1, Storage, Quadrant b
12 H1Bb Horizontal CCD Clock, Phase 1, Barrier, Quadrant b
13 H2Bb Horizontal CCD Clock, Phase 2, Barrier, Quadrant b
14 H2SLb Horizontal CCD Clock, Phase 2, Storage, Last Phase, Quadrant b
15 OGb Output Gate, Quadrant b
16 Rb Reset Gate, Quadrant b
17 RDb Reset Drain, Quadrant b
18 GND Ground
19 VOUTb Video Output, Quadrant b
KAI−02150
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Table 5. CLCC PACKAGE PIN DESCRIPTION (continued)
Pin DescriptionName
20 VDDb Output Amplifier Supply, Quadrant b
21 V2B Vertical CCD Clock, Phase 2, Bottom
22 V1B Vertical CCD Clock, Phase 1, Bottom
23 V4B Vertical CCD Clock, Phase 4, Bottom
24 V3B Vertical CCD Clock, Phase 3, Bottom
25 DevID Device Identification
26 V3T Vertical CCD Clock, Phase 3, Top
27 V4T Vertical CCD Clock, Phase 4, Top
28 V1T Vertical CCD Clock, Phase 1, Top
29 V2T Vertical CCD Clock, Phase 2, Top
30 VDDd Output Amplifier Supply, Quadrant d
31 VOUTd Video Output, Quadrant d
32 GND Ground
33 RDd Reset Drain, Quadrant d
34 Rd Reset Gate, Quadrant d
35 OGd Output Gate, Quadrant d
36 H2SLd Horizontal CCD Clock, Phase 2, Storage, Last Phase, Quadrant d
37 H2Bd Horizontal CCD Clock, Phase 2, Barrier, Quadrant d
38 H1Bd Horizontal CCD Clock, Phase 1, Barrier, Quadrant d
39 H1Sd Horizontal CCD Clock, Phase 1, Storage, Quadrant d
40 H2Sd Horizontal CCD Clock, Phase 2, Storage, Quadrant d
41 SUB Substrate
42 H2Sc Horizontal CCD Clock, Phase 2, Storage, Quadrant c
43 H1Sc Horizontal CCD Clock, Phase 1, Storage, Quadrant c
44 H1Bc Horizontal CCD Clock, Phase 1, Barrier, Quadrant c
45 H2Bc Horizontal CCD Clock, Phase 2, Barrier, Quadrant c
46 H2SLc Horizontal CCD Clock, Phase 2, Storage, Last Phase, Quadrant c
47 OGc Output Gate, Quadrant c
48 Rc Reset Gate, Quadrant c
49 RDc Reset Drain, Quadrant c
50 GND Ground
51 VOUTc Video Output, Quadrant c
52 VDDc Output Amplifier Supply, Quadrant c
53 V2T Vertical CCD Clock, Phase 2, Top
54 V1T Vertical CCD Clock, Phase 1, Top
55 V4T Vertical CCD Clock, Phase 4, Top
56 V3T Vertical CCD Clock, Phase 3, Top
57 ESD ESD Protection Disable
58 V3B Vertical CCD Clock, Phase 3, Bottom
59 V4B Vertical CCD Clock, Phase 4, Bottom
60 V1B Vertical CCD Clock, Phase 1, Bottom
61 V2B Vertical CCD Clock, Phase 2, Bottom
62 VDDa Output Amplifier Supply, Quadrant a
63 VOUTa Video Output, Quadrant a
64 GND Ground
1. Liked named pins are internally connected and should have a common drive signal.
KAI−02150
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10
IMAGING PERFORMANCE
Typical Operational Conditions
Unless otherwise noted, the Imaging Performance Specifications are measured using the following conditions.
Table 6. TYPICAL OPERATIONAL CONDITIONS
Description Condition Notes
Light Source Continuous Red, Green and Blue LED Illumination. 1
Operation Nominal Operating Voltages and Timing.
1. For monochrome sensor, only green LED used.
Specifications
Table 7. PERFORMANCE SPECIFICATIONS
Description Symbol Min. Nom. Max. Unit Sampling
Plan
Temperature
Tested at
(5C)
ALL CONFIGURATIONS
Dark Field Global Non-Uniformity DSNU − − 2.0 mVpp Die 27, 40
Bright Field Global Non-Uniformity
(Note 1) − 2.0 5.0 % rms Die 27, 40
Bright Field Global Peak to Peak
Non-Uniformity (Note 1) PRNU − 5.0 15.0 % pp Die 27, 40
Bright Field Center Non-Uniformity
(Note 1) − 1.0 2.0 % rms Die 27, 40
Maximum Photoresponse Non-Linearity
(Note 2) NL − 2 − % Design
Maximum Gain Difference between
Outputs (Note 2) DG− 10 − % Design
Maximum Signal Error due to
Non-Linearity Differences (Note 2) DNL − 1 − % Design
Horizontal CCD Charge Capacity HNe − 55 − ke−Design
Vertical CCD Charge Capacity VNe − 45 − ke−Design
Photodiode Charge Capacity (Note 3) PNe − 20 − ke−Die 27, 40
Horizontal CCD Charge Transfer
Efficiency HCTTE 0.999995 0.999999 − Die
Vertical CCD Charge Transfer Efficiency VCTE 0.999995 0.999999 − Die
Photodiode Dark Current IPD − 7 70 e/p/s Die 40
Vertical CCD Dark Current IVD − 100 300 e/p/s Die 40
Image Lag Lag − − 10 e−Design
Anti-Blooming Factor XAB 300 − − Design
Vertical Smear Smr − −100 − dB Design
Read Noise (Note 4) ne−T − 12 − e− rms Design
Dynamic Range (Notes 4, 5) DR − 64 − dB Design
Output Amplifier DC Offset VODC − 9.4 − V Die 27, 40
Output Amplifier Bandwidth (Note 6) f−3db − 250 − MHz Die
Output Amplifier Impedance ROUT − 127 − WDie 27, 40
Output Amplifier Sensitivity DV/DN− 34 − mV/e−Design
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Table 7. PERFORMANCE SPECIFICATIONS (continued)
Description
Temperature
Tested at
(5C)
Sampling
Plan
UnitMax.Nom.Min.Symbol
KAI−02150−ABA, KAI−02150−QBA AND KAI−02150−PBA CONFIGURATIONS (Note 7)
Peak Quantum Efficiency QEMAX − 44 − % Design
Peak Quantum Efficiency Wavelength lQE − 480 − nm Design
KAI−02150−FBA AND KAI−02150−QBA GEN2 COLOR CONFIGURATIONS WITH MAR GLASS
Peak Quantum Efficiency
Blue
Green
Red
QEMAX −
−
−
38
37
31
−
−
−
% Design
Peak Quantum Efficiency Wavelength
Blue
Green
Red
lQE −
−
−
460
530
605
−
−
−
nm Design
KAI−02150−FBA GEN2 COLOR CONFIGURATIONS WITH CLEAR GLASS
Peak Quantum Efficiency
Blue
Green
Red
QEMAX −
−
−
35
34
29
−
−
−
% Design
Peak Quantum Efficiency Wavelength
Blue
Green
Red
lQE −
−
−
460
530
605
−
−
−
nm Design
KAI−02150−CBA AND KAI−02150−PBA GEN1 COLOR CONFIGURATIONS WITH MAR GLASS (Note 7)
Peak Quantum Efficiency
Blue
Green
Red
QEMAX −
−
−
39
37
29
−
−
−
% Design
Peak Quantum Efficiency Wavelength
Blue
Green
Red
lQE −
−
−
470
540
620
−
−
−
nm Design
KAI−02150−CBA GEN1 COLOR CONFIGURATION WITH CLEAR GLASS (Note 7)
Peak Quantum Efficiency
Blue
Green
Red
QEMAX −
−
−
36
34
27
−
−
−
% Design
Peak Quantum Efficiency Wavelength
Blue
Green
Red
lQE −
−
−
470
540
620
−
−
−
nm Design
1. Per color.
2. Value is over the range of 10% to 90% of photodiode saturation.
3. The operating value of the substrate voltage, VAB, will be marked on the shipping container for each device. The value of VAB is set such
that the photodiode charge capacity is 680 mV.
4. At 40 MHz.
5. Uses 20LOG (PNe /n
e−T).
6. Assumes 5 pF load.
7. This color filter set configuration (Gen1) is not recommended for new designs.
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TYPICAL PERFORMANCE CUR VES
Quantum Efficiency
Monochrome with Microlens
Figure 7. Monochrome with Microlens Quantum Efficiency
NOTE: The PGA and CLCC versions have different quantum efficiencies due to differences in the cover glass transmission.
See Figure 35: Cover Glass Transmission for more details.
Monochrome without Microlens
Figure 8. Monochrome without Microlens Quantum Efficiency
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Color (Bayer RGB) with Microlens and MAR Cover Glass (Gen2 and Gen1 CFA)
Figure 9. MAR Glass Color (Bayer) with Microlens Quantum Efficiency
Color (Bayer RGB) with Microlens and Clear Cover Glass (Gen2 and Gen1 CFA)
Figure 10. Clear Glass Color (Bayer) with Microlens Quantum Efficiency
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Color (TRUESENSE Sparse CFA) with Microlens (Gen2 and Gen1 CFA)
Figure 11. Color (TRUESENSE Sparse CFA) with Microlens Quantum Efficiency
Angular Quantum Efficiency
For the curves marked “Horizontal”, the incident light angle is varied in a plane parallel to the HCCD.
For the curves marked “Vertical”, the incident light angle is varied in a plane parallel to the VCCD.
Monochrome with Microlens
Figure 12. Monochrome with Microlens Angular Quantum Efficiency
0
10
20
30
40
50
60
70
80
90
100
−30 −20 −10 0 10 20 30
Angle (degrees)
Relative Quantum Efficiency (%)
Vertical
Horizontal
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Dark Current vs. Temperature
Figure 13. Dark Current vs. Temperature
0.1
1
10
100
1000
10000
2.9 3.0 3.1 3.2 3.3 3.4
Dark Current (e/s)
1000/T (K)
T (C)
VCCD
Photodiode
60 50 40 30 2172
Power-Estimated
Figure 14. Power
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
10 15 20 25 30 35 40
HCCD Frequency (MHz)
Power (W)
Single
Dual
Quad
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DEFECT DEFINITIONS
Table 8. OPERATION CONDITIONS FOR DEFECT TESTING AT 405C
Description Condition Notes
Operational Mode Two Outputs, Using VOUTa and VOUTc, Continuous Readout
HCCD Clock Frequency 10 MHz
Pixels per Line 2,160 1
Lines per Frame 672 2
Line Time 218.9 ms
Frame Time 147.1 ms
Photodiode Integration Time Mode A: PD_Tint = Frame Time = 147.1 ms, No Electronic Shutter Used
Mode B: PD_Tint = 33 ms, Electronic Shutter Used
VCCD Integration Time 125.2 ms 3
Temperature 40°C
Light Source Continuous Red, Green and Blue LED Illumination 4
Operation Nominal Operating Voltages and Timing
1. Horizontal overclocking used.
2. Vertical overclocking used.
3. VCCD Integration Time = 572 lines × Line Time, which is the total time a pixel will spend in the VCCD registers.
4. For monochrome sensor, only the green LED is used.
Table 9. DEFECT DEFINITIONS FOR TESTING AT 405C
Description Definition Standard
Grade Grade 2 Notes
Major Dark Field Defective Bright Pixel PD_Tint = Mode A → Defect ≥ 51 mV
or
PD_Tint = Mode B → Defect ≥ 12 mV
20 20 1
Major Bright Field Defective Dark Pixel Defect ≥ 12% 20 20 1
Minor Dark Field Defective Bright Pixel PD_Tint = Mode A → Defect ≥ 26 mV
or
PD_Tint = Mode B → Defect ≥ 6 mV
200 200
Cluster Defect (Standard Grade) A group of 2 to 10 contiguous major defective pixels,
but no more than 2 adjacent defect horizontally. 8 N/A 2
Cluster Defect (Grade 2) A group of 2 to 10 contiguous major defective pixels. N/A 10 2
Column Defect A group of more than 10 contiguous major defective
pixels along a single column. 0 0 2
1. For the color device (KAI−02150−FBA, KAI−02150−CBA, KAI−02150−QBA, or KAI−02150−PBA), a bright field defective pixel deviates by
12% with respect to pixels of the same color.
2. Column and cluster defects are separated by no less than two (2) good pixels in any direction (excluding single pixel defects).
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Table 10. OPERATION CONDITIONS FOR DEFECT TESTING AT 275C
Description Condition Notes
Operational Mode Two Outputs, Using VOUTa and VOUTc, Continuous Readout
HCCD Clock Frequency 20 MHz
Pixels per Line 2,160 1
Lines per Frame 672 2
Line Time 109.8 ms
Frame Time 73.8 ms
Photodiode Integration Time (PD_Tint) Mode A: PD_Tint = Frame Time = 73.8 ms, No Electronic Shutter Used
Mode B: PD_Tint = 33 ms, Electronic Shutter Used
VCCD Integration Time 62.8 ms 3
Temperature 27°C
Light Source Continuous Red, Green and Blue LED Illumination 4
Operation Nominal Operating Voltages and Timing
1. Horizontal overclocking used.
2. Vertical overclocking used.
3. VCCD Integration Time = 572 lines × Line Time, which is the total time a pixel will spend in the VCCD registers.
4. For monochrome sensor, only the green LED is used.
Table 11. DEFECT DEFINITIONS FOR TESTING AT 405C
Description Definition Standard
Grade Grade 2 Notes
Major Dark Field Defective Bright Pixel PD_Tint = Mode A → Defect ≥ 8 mV
or
PD_Tint = Mode B → Defect ≥ 4 mV
20 20 1
Major Bright Field Defective Dark Pixel Defect ≥ 12% 20 20 1
Cluster Defect (Standard Grade) A group of 2 to 10 contiguous major defective pixels,
but no more than 2 adjacent defect horizontally. 8 N/A 2
Cluster Defect (Grade 2) A group of 2 to 10 contiguous major defective pixels. N/A 10 2
Column Defect A group of more than 10 contiguous major defective
pixels along a single column. 0 0 2
1. For the color device (KAI−02150−FBA, KAI−02150−CBA, KAI−02150−QBA, or KAI−02150−PBA), a bright field defective pixel deviates by
12% with respect to pixels of the same color.
2. Column and cluster defects are separated by no less than two (2) good pixels in any direction (excluding single pixel defects).
Defect Map
The defect map supplied with each sensor is based upon
testing at an ambient (27°C) temperature. Minor point
defects are not included in the defect map. All defective
pixels are reference to pixel 1, 1 in the defect maps. See
Figure 16: Regions of Interest for the location of pixel 1, 1.
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TEST DEFINITIONS
Test Regions of Interest
Image Area ROI: Pixel (1, 1) to Pixel (1960, 1120)
Active Area ROI: Pixel (21, 21) to Pixel (1940, 1100)
Center ROI: Pixel (931, 511) to Pixel (1030, 610)
Only the Active Area ROI pixels are used for performance
and defect tests.
Overclocking
The test system timing is configured such that the sensor
is overclocked in both the vertical and horizontal directions.
See Figure 16 for a pictorial representation of the regions of
interest.
Figure 16. Regions of Interest
Horizontal Overclock
VOUTa
1, 1
21,
21
Pixel
Pixel
VOUTc
12 Dark Rows
22 Dark Columns
20 Buffer Rows
20 Buffer Columns
20 Buffer Columns
22 Dark Columns
1920 x 1080
Active Pixels
12 Dark Rows
20 Buffer Rows
Tests
Dark Field Global Non-Uniformity
This test is performed under dark field conditions.
The sensor is partitioned into 144 sub regions of interest,
each of which is 120 by 120 pixels in size. See Figure 17:
Test Sub Regions of Interest. The average signal level of
each of the 144 sub regions of interest is calculated.
The signal level of each of the sub regions of interest is
calculated using the following formula:
Signal of ROI[i] +(ROI Average in Counts *
Units : mVpp (millivolts Peak to Peak)
*Horizontal Overclock Average in Counts) @
@mV per Count
Where i = 1 to 144. During this calculation on the 144 sub
regions of interest, the maximum and minimum signal levels
are found. The dark field global uniformity is then calculated
as the maximum signal found minus the minimum signal
level found.
Global Non-Uniformity
This test is performed with the imager illuminated to a level
such that the output is at 70% of saturation (approximately
476 mV). Prior to this test being performed the substrate
voltage has been set such that the charge capacity of the
sensor is 680 mV. Global non-uniformity is defined as
Global Non−Uniformity +100 @ǒActive Area Standard Deviation
Active Area Signal Ǔ
Active Area Signal = Active Area Average − Dark Column Average
Units : % rms
Global Peak to Peak Non-Uniformity
This test is performed with the imager illuminated to
a level such that the output is at 70% of saturation
(approximately 47 6 mV). Prior to this test being performed
the substrate voltage has been set such that the charge
capacity of the sensor is 680 mV. The sensor is partitioned
into 144 sub regions of interest, each of which is 120 by 120
pixels in size. See Figure 17: Test Sub Regions of Interest.
The average signal level of each of the 144 sub regions of
interest (ROI) is calculated. The signal level of each of the
sub regions of interest is calculated using the following
formula:
Signal of ROI[i] +(ROI Average in Counts *
*Horizontal Overclock Average in Counts) @
@mV per Count
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Where i = 1 to 144. During this calculation on the 144 sub
regions of interest, the maximum and minimum signal levels
are found. The global peak to peak uniformity is then
calculated as:
Global Uniformity +100 @ǒMax. Signal *Min. Signal
Active Area Signal Ǔ
Units : % pp
Center Non-Uniformity
This test is performed with the imager illuminated to
a level such that the output is at 70% of saturation
(approximately 47 6 mV). Prior to this test being performed
the substrate voltage has been set such that the charge
capacity of the sensor is 680 mV. Defects are excluded for
the calculation of this test. This test is performed on the
center 100 by 100 pixels of the sensor. Center uniformity is
defined as:
Center ROI Uniformity +100 @ǒCenter ROI Standard Deviation
Center ROI Signal Ǔ
Center ROI Signal = Center ROI Average − Dark Colum Average
Units : % rms
Dark Field Defect Test
This test is performed under dark field conditions.
The sensor is partitioned into 144 sub regions of interest,
each of which is 120 by 120 pixels in size. In each region of
interest, the median value of all pixels is found. For each
region of interest, a pixel is marked defective if it is greater
than or equal to the median value of that region of interest
plus the defect threshold specified in the “Defect
Definitions” section.
Bright Field Defect Test
This test is performed with the imager illuminated to
a level such that the output is at approximately 476 mV.
Prior to this test being performed the substrate voltage has
been set such that the charge capacity of the sensor is
680 mV. The average signal level of all active pixels is
found. The bright and dark thresholds are set as:
Dark Defect Threshold = Active Area Signal @Threshold
Bright Defect Threshold = Active Area Signal @Threshold
The sensor is then partitioned into 144 sub regions of
interest, each of which is 120 by 120 pixels in size. In each
region of interest, the average value of all pixels is found.
For each region of interest, a pixel is marked defective if it
is greater than or equal to the median value of that region of
interest plus the bright threshold specified or if it is less than
or equal to the median value of that region of interest minus
the dark threshold specified.
Example for major bright field defective pixels:
•Average value of all active pixels is found to be 476 mV.
•Dark defect threshold: 476 mV ⋅ 12 % = 57 mV.
•Bright defect threshold: 476 mV ⋅ 12 % = 57 mV.
•Region of interest #1 selected. This region of interest is
pixels 21, 21 to pixels 140, 140.
♦Median of this region of interest is found to be
470 mV.
♦Any pixel in this region of interest that is
≥ (470 + 57 mV) 527 mV in intensity will be marked
defective.
♦Any pixel in this region of interest that is
≤ (470 − 57 mV) 413 mV in intensity will be marked
defective.
•All remaining 144 sub regions of interest are analyzed
for defective pixels in the same manner.
Test Sub Regions of Interest
Figure 17. Test Sub Regions of Interest
Pixel (21,21)
Pixel (1940,1100)
VOUTa
12345678910
17 18 19 20 21 22 23 24 25 26
33 34 35 36 37 38 39 40 41 42
49 50 51 52 53 54 55 56 57 58
65 66 67 68 69 70 71 72 73 74
81 82 83 84 85 86 87 88 89 90
97 98 99 100 101 102 103 104 105 106
113 114 115 116 117 118 119 120 121 122
129 130 131 132 133 134 135 136 137 138
11 12 13 14 15 16
27 28 29 30 31 32
43 44 45 46 47 48
59 60 61 62 63 64
75 76 77 78 79 80
91 92 93 94 95 96
107 108 109 110 111 112
123 124 125 126 127 128
139 140 141 142 143 144
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OPERATION
Absolute Maximum Ratings
Absolute maximum rating is defined as a level or
condition that should not be exceeded at any time per the
description. If the level or the condition is exceeded,
the device will be degraded and may be damaged. Operation
at these values will reduce MTTF.
Table 12. ABSOLUTE MAXIMUM RATINGS
Description Symbol Minimum Maximum Unit Notes
Operating Temperature TOP −50 70 °C 1
Humidity RH 5 90 % 2
Output Bias Current IOUT − 60 mA 3
Off-Chip Load CL− 10 pF
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality
should not be assumed, damage may occur and reliability may be af fected.
1. Noise performance will degrade at higher temperatures.
2. T = 25°C. Excessive humidity will degrade MTTF.
3. Total for all outputs. Maximum current is −15 mA for each output. Avoid shorting output pins to ground or any low impedance source during
operation. Amplifier bandwidth increases at higher current and lower load capacitance at the expense of reduced gain (sensitivity).
Table 13. ABSOLUTE MAXIMUM VOLTAGE RATINGS BETWEEN PINS AND GROUND
Description Minimum Maximum Unit Notes
VDDa, VOUTa−0.4 17.5 V 1
RDa−0.4 15.5 V 1
V1B, V1T ESD − 0.4 ESD + 24.0 V
V2B, V2T, V3B, V3T, V4B, V4T ESD − 0.4 ESD + 14.0 V
H1Sa, H1Ba, H2Sa, H2Ba, H2SLa, Ra, OGaESD − 0.4 ESD + 14.0 V 1
ESD −10.0 0.0 V
SUB −0.4 40.0 V 2
1. a denotes a, b, c or d.
2. Refer to Application Note Using Interline CCD Image Sensors in High Intensity Visible Lighting Conditions
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Power-Up and Power-Down Sequence
Adherence to the power-up and power-down sequence is critical. Failure to follow the proper power-up and power-down
sequences may cause damage to the sensor.
Figure 18. Power-Up and Power-Down Sequence
VDD
SUB
ESD VCCD
Low HCCD
Low
Time
V+
V−
Do Not Pulse the Electronic Shutter until ESD is Stable
Activate All Other Biases when ESD is Stable and Sub is above 3 V
1. Activate all other biases when ESD is stable and SUB is above 3 V.
2. Do not pulse the electronic shutter until ESD is stable.
3. VDD cannot be +15 V when SUB is 0 V.
4. The image sensor can be protected from an accidental improper ESD voltage by current limiting the SUB current to less than 10 mA. SUB
and VDD must always be greater than GND. ESD must always be less than GND. Placing diodes between SUB, VDD, ESD and groun
d
will protect the sensor from accidental overshoots of SUB, VDD and ESD during power on and power off. See the figure below.
Notes:
The VCCD clock waveform must not have a negative overshoot more than 0.4 V below the ESD voltage.
Figure 19. VCCD Clock Waveform
All VCCD Clock Absolute
Maximum Overshoot of 0.4 V
0.0 V
ESD
ESD − 0.4 V
Example of external diode protection for SUB, VDD and ESD.a denotes a, b, c or d.
Figure 20. Example of External Diode Protection
ESD
GND
VDD
a
SUB
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DC Bias Operating Conditions
Table 14. DC BIAS OPERATING CONDITIONS
Description Pins Symbol Min. Nom. Max. Unit Max. DC
Current Notes
Reset Drain RDaRD 11.8 12.0 12.2 V 10 mA1
Output Gate OGaOG −2.2 −2.0 −1.8 V10 mA1
Output Amplifier Supply VDDaVDD 14.5 15.0 15.5 V 11.0 mA 1, 2
Ground GND GND 0.0 0.0 0.0 V −1.0 mA
Substrate SUB VSUB 5.0 VAB VDD V50 mA3, 8
ESD Protection Disable ESD ESD −9.5 −9.0 Vx_L V 50 mA6, 7, 9
Output Bias Current VOUTaIOUT −3.0 −7.0 −10.0 mA − 1, 4, 5
1. a denotes a, b, c or d.
2. The maximum DC current is for one output. IDD = IOUT + ISS. See Figure 21.
3. The operating value of the substrate voltage, VAB, will be marked on the shipping container for each device. The value of VAB is set such
that the photodiode charge capacity is the nominal PNe (see Specifications).
4. An output load sink must be applied to each VOUT pin to activate each output amplifier.
5. Nominal value required for 40 MHz operation per output. May be reduced for slower data rates and lower noise.
6. Adherence to the power-up and power-down sequence is critical. See Power Up and Power Down Sequence section.
7. ESD maximum value must be less than or equal to V1_L + 0.4 V and V2_L + 0.4 V.
8. Refer to Application Note Using Interline CCD Image Sensors in High Intensity Visible Lighting Conditions.
9. Where Vx_L is the level set for V1_L, V2_L, V3_L, or V4_L in the application.
Figure 21. Output Amplifier
Source
Follower
#1
Source
Follower
#2
Source
Follower
#3
Floating
Diffusion
ISS
IDD
IOUT
VOUTa
VDDa
Ra
RDa
HCCD
OGa
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AC Operating Conditions
Table 15. CLOCK LEVELS
Description Pins
(Note 1) Symbol Level Min. Nom. Max. Unit Capacitance
(Note 2)
Vertical CCD Clock, Phase 1 V1B, V1T V1_L Low −8.2 −8.0 −7.8 V12 nF
(Note 6)
V1_M Mid −0.2 0.0 0.2
V1_H High 11.5 12.0 12.5
Vertical CCD Clock, Phase 2 V2B, V2T V2_L Low −8.2 −8.0 −7.8 V12 nF
(Note 6)
V2_H High −0.2 0.0 0.2
Vertical CCD Clock, Phase 3 V3B, V3T V3_L Low −8.2 −8.0 −7.8 V12 nF
(Note 6)
V3_H High −0.2 0.0 0.2
Vertical CCD Clock, Phase 4 V4B, V4T V4_L Low −8.2 −8.0 −7.8 V12 nF
(Note 6)
V4_H High −0.2 0.0 0.2
Horizontal CCD Clock,
Phase 1 Storage H1SaH1S_L Low −5.2
(Note 7) −4.0 −3.8 V170 pF
(Note 6)
H1S_A Amplitude 3.8 4.0 5.2
(Note 7)
Horizontal CCD Clock,
Phase 1 Barrier H1BaH1B_L Low −5.2
(Note 7) −4.0 −3.8 V110 pF
(Note 6)
H1B_A Amplitude 3.8 4.0 5.2
(Note 7)
Horizontal CCD Clock,
Phase 2 Storage H2SaH2S_L Low −5.2
(Note 7) −4.0 −3.8 V170 pF
(Note 6)
H2S_A Amplitude 3.8 4.0 5.2
(Note 7)
Horizontal CCD Clock,
Phase 2 Barrier H2BaH2B_L Low −5.2
(Note 7) −4.0 −3.8 V110 pF
(Note 6)
H2B_A Amplitude 3.8 4.0 5.2
(Note 7)
Horizontal CCD Clock,
Phase 2 Last Phase (Note 3) H2SLaH2SL_L Low −5.2 −5.0 −4.8 V20 pF
(Note 6)
H2SL_A Amplitude 4.8 5.0 5.2
Reset Gate RaR_L
(Note 4) Low −3.5 −2.0 −1.5 V16 pF
(Note 6)
R_H High 2.5 3.0 4.0
Electronic Shutter (Note 5) SUB VES High 29.0 30.0 40.0 V 800 pF
(Note 6)
1. a denotes a, b, c or d.
2. Capacitance is total for all like named pins.
3. Use separate clock driver for improved speed performance.
4. Reset low should be set to –3 V for signal levels greater than 40,000 electrons.
5. Refer to Application Note Using Interline CCD Image Sensors in High Intensity Visible Lighting Conditions.
6. Capacitance values are estimated.
7. If the minimum horizontal clock low level is used (–5.2 V), then the maximum horizontal clock amplitude should be used (5.2 V amplitude)
to create a –5.2 V to 0.0 V clock. If a 5 V clock driver is used, the horizontal low level should be set to –5.0 V and the high level should be
a set to 0.0 V.
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The figure below shows the DC bias (VSUB) and AC
clock (VES) applied to the SUB pin. Both the DC bias and
AC clock are referenced to ground.
Figure 22. DC Bias and AC Clock Applied to the SUB Pin
VSUB
VES
GND GND
Device Identification
The device identification pin (DevID) may be used to
determine which Truesense Imaging 5.5 micron pixel
interline CCD sensor is being used.
Table 16.
Description Pins Symbol Min. Nom. Max. Unit Max. DC
Current Notes
Device Identification DevID DevID 49,000 55,000 61,000 W50 mA1, 2, 3
1. Nominal value subject to verification and/or change during release of preliminary specifications.
2. If the Device Identification is not used, it may be left disconnected.
3. After Device Identification resistance has been read during camera initialization, it is recommended that the circuit be disabled to prevent
localized heating of the sensor due to current flow through the R_DeviceID resistor.
Recommended Circuit
Note that V1 must be a different value than V2.
Figure 23. Device Identification Recommended Circuit
ADC
R_external
V1 V2
DevID
GND
KAI−02150
R_DeviceID
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26
TIMING
Table 17. REQUIREMENTS AND CHARACTERISTICS
Description Symbol Min. Nom. Max. Unit Notes
Photodiode Transfer tPD 1.0 − − ms
VCCD Leading Pedestal t3P 4.0 − − ms
VCCD Trailing Pedestal t3D 4.0 − − ms
VCCD Transfer Delay tD1.0 − − ms
VCCD Transfer tV1.0 − − ms
VCCD Clock Cross-Over VVCR 75 − 100 %
VCCD Rise, Fall Times tVR, tVF 5 − 10 % 2, 3
HCCD Delay tHS 0.2 − − ms
HCCD Transfer te25.0 − − ns
Shutter Transfer tSUB 1.0 − − ms
Shutter Delay tHD 1.0 − − ms
Reset Pulse tR2.5 − − ns
Reset − Video Delay tRV − 2.2 − ns
H2SL − Video Delay tHV − 3.1 − ns
Line Time tLINE 27.0 − − msDual HCCD Readout
52.1 − − msSingle HCCD Readout
Frame Time tFRAME 15.5 − − ms Quad HCCD Readout
31.0 − − ms Dual HCCD Readout
59.6 − − ms Single HCCD Readout
1. Refer to timing diagrams as shown in Figure 24, Figure 25, Figure 26, Figure 27 and Figure 28.
2. Refer to Figure 28: VCCD Clock Edge Alignment.
3. Relative to the pulse width.
Timing Diagrams
The timing sequence for the clocked device pins may be
represented a s one of seven patterns (P1−P7) as shown in the
table below. The patterns are defined in Figure 24 and
Figure 25. Contact Truesense Imaging Application
Engineering for other readout modes.
Table 18. TIMING DIAGRAMS
Device Pin Quad Readout Dual Readout
VOUTa, VOUTb Dual Readout
VOUTa, VOUTc Single Readout
VOUTa
V1T P1T P1B P1T P1B
V2T P2T P4B P2T P4B
V3T P3T P3B P3T P3B
V4T P4T P2B P4T P2B
V1B P1B
V2B P2B
V3B P3B
V4B P4B
H1Sa P5
H1Ba P5
H2Sa (Note 2) P6
H2Ba P6
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Table 18. TIMING DIAGRAMS (continued)
Device Pin Single Readout
VOUTa
Dual Readout
VOUTa, VOUTc
Dual Readout
VOUTa, VOUTb
Quad Readout
Ra P7
H1Sb P5 P5
H1Bb P5 P6
H2Sb (Note 2) P6 P6
H2Bb P6 P5
Rb P7 P7 (Note 1) or Off (Note 3) P7 (Note 1) or Off (Note 3)
H1Sc P5 P5 (Note 1) or Off (Note 3) P5 P5 (Note 1) or Off (Note 3)
H1Bc P5 P5 (Note 1) or Off (Note 3) P5 P5 (Note 1) or Off (Note 3)
H2Sc (Note 2) P6 P6 (Note 1) or Off (Note 3) P6 P6 (Note 1) or Off (Note 3)
H2Bc P6 P6 (Note 1) or Off (Note 3) P6 P6 (Note 1) or Off (Note 3)
Rc P7 P7 (Note 1) or Off (Note 3) P7 P7 (Note 1) or Off (Note 3)
H1Sd P5 P5 (Note 1) or Off (Note 3) P5 P5 (Note 1) or Off (Note 3)
H1Bd P5 P5 (Note 1) or Off (Note 3) P6 P5 (Note 1) or Off (Note 3)
H2Sd (Note 2) P6 P6 (Note 1) or Off (Note 3) P6 P6 (Note 1) or Off (Note 3)
H2Bd P6 P6 (Note 1) or Off (Note 3) P5 P6 (Note 1) or Off (Note 3)
Rd P7 P7 (Note 1) or Off (Note 3) P7 (Note 1) or Off (Note 3) P7 (Note 1) or Off (Note 3)
#Lines/Frame
(Minimum) 572 1144 572 1144
#Pixels/Line
(Minimum) 1013 2026
1. For optimal performance of the sensor. May be clocked at a lower frequency. If clocked at a lower frequency, the frequency selected should
be a multiple of the frequency used on the a and b register.
2. H2SLx follows the same pattern as H2Sx For optimal speed performance, use a separate clock driver.
3. Off = +5 V. Note that there may be operating conditions (high temperature and/or very bright light sources) that will cause blooming from the
unused c/d register into the image area.
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Photodiode Transfer Timing
A row of charge is transferred to the HCCD on the falling
edge of V1 as indicated in the P1 pattern below. Using this
timing sequence, the leading dummy row or line is
combined with the first dark row in the HCCD. The “Last
Line” is dependent on readout mode – either 572 or 1144
minimum counts required. It is important to note that, in
general, the rising edge of a vertical clock (patterns P1−P4)
should be coincident or slightly leading a falling edge at the
same time interval. This is particularly true at the point
where P1 returns from the high (3rd level) state to the
mid-state when P4 transitions from the low state to the high
state.
Figure 24. Photodiode Transfer Timing
Last Line L1 + Dummy Line
P1B
P2B
P3B
P4B
Pattern
L2
P1T
P2T
P3T
P4T
tv
tv/2
tpd
tv/2 tv/2
td
tdt3p t3d
tv
ths
tv
tv/2
tv
ths
tv/2 tv/2
P5
P6
P7
1 2 3 4 5 6
Line and Pixel Timing
Each row of charge is transferred to the output, as
illustrated below, on the falling edge of H2SL (indicated as
P6 pattern). The number of pixels in a row is dependent on
readout mode – either 1013 or 2026 minimum counts
required.
Figure 25. Line and Pixel Timing
P1T
P5
P6
P7
Pixel
n
Pixel
1Pixel
34
t
line
tv
ths
te
tr
te/2
VOUT
Pattern
P1B tv
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Pixel Timing Detail
Figure 26. Pixel Timing Detail
P5
P6
P7
VOUT
thv trv
Frame/Electronic Shutter Timing
The SUB pin may be optionally clocked to provide
electronic shuttering capability as shown below. The resulting photodiode integration time is defined from the
falling edge of SUB to the falling edge of V1 (P1 pattern).
Figure 27. Frame/Electronic Shutter Timing
P1T/B
P6
SUB tint
t
frame
thd
thd
tsub
Pattern
VCCD Clock Edge Alignment
Figure 28. VCCD Clock Edge Alignment
VVCR
90%
10%
tVF
tVR
tV
tV
tVF tVR
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STORAGE AND HANDLING
Table 19. STORAGE CONDITIONS
Description Symbol Minimum Maximum Unit Notes
Storage Temperature TST −40 80 °C 1
Humidity RH 5 90 % 2
1. Long-term storage toward the maximum temperature will accelerate color filter degradation.
2. T = 25°C. Excessive humidity will degrade MTTF.
For information on ESD and cover glass care and
cleanliness, please download the Image Sensor Handling
and Best Practices Application Note (AN52561/D) from
www.onsemi.com.
For information on environmental exposure, please
download the Using Interline CCD Image Sensors in High
Intensity Lighting Conditions Application Note
(AND9183/D) from www.onsemi.com.
For information on soldering recommendations, please
download the Soldering and Mounting Techniques
Reference Manual (SOLDERRM/D) from
www.onsemi.com.
For quality and reliability information, please download
the Quality & Reliability Handbook (HBD851/D) from
www.onsemi.com.
For information on device numbering and ordering codes,
please download the Device Nomenclature technical note
(TND310/D) from www.onsemi.com.
For information on Standard terms and Conditions of
Sale, please download Terms and Conditions from
www.onsemi.com.
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MECHANICAL INFORMATION
PGA Completed Assembly
Figure 30. PGA Completed Assembly
1. See Ordering Information for marking code.
2. No materials to interfere with clearance through guide holes.
3. The center of the active image is nominally at the center of the package.
4. Die rotation < 0.5 degrees.
5. Glass rotation < 1.5 degrees with respect to package outer edges for all sealed configurations.
6. Internal traces may be exposed on sides of package. Do not allow metal to contact sides of ceramic package.
7. Recommended mounting screws:1.6 × 0.35 mm (ISO Standard); 0–80 (Unified Fine Thread Standard).
8. Units: millimeters.
Notes:
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PGA Clear Cover Glass
Figure 34. PGA Clear Cover Glass
1. Dust/Scratch Count – 12 micron maximum
2. Units: IN
Notes:
Cover Glass Transmission
Figure 35. Cover Glass Transmission
NOTE: PGA and CLCC MAR transmission data differ due to in-spec differences from glass vendor.
0
10
20
30
40
50
60
70
80
90
100
200 300 400 500 600 700 800 900
Transmission (%)
Wavelength (nm)
PGA MAR
CLCC MAR
PGA Clear
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SHIPPING CONFIGURATION
Cover Glass Protective Tape
Cover glass protective tape, as shown in Figure 36, is
utilized to help ensure the cleanliness of the cover glass
during transportation and camera manufacturing. This
protective tape is not intended to be optically correct, and
should b e removed prior to any image testing. The protective
tape should be removed in an ionized air stream to prevent
static build-up and the attraction of particles. The following
part numbers will have the protective tape applied:
Table 20.
Part Number Description
KAI−02150−CBA−JB−B2 Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear Cover Glass (No Coatings),
Grade 2
KAI−02150−CBA−JB−AE Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear Cover Glass (No Coatings),
Engineering Grade
KAI−02150−CBA−JB−B2−T Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear Cover Glass (No Coatings),
Grade 2, Packed in Trays
Table 21.
Criteria Description
Placement Per the drawing. The lid tape shall not overhang the edge of the package or mounting holes. The lid tape
always overhangs the top of the glass (chamfers not included).
Tab Location The tape tab is located near pin 68.
Scratches The tape application equipment will make slight scratches on the lid tape. This is allowed.
Figure 36. Cover Glass Protective Tape
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Tray Packing
The following part numbers are packed in bricks of 6
trays, each tray containing 32 image sensors, for a total of
192 image sensors per brick. The minimum order and
multiple quantities for this configuration are 192 image
sensors.
Table 22.
Part Number Description
KAI−02150−CBA−JB−B2−T Color (Bayer RGB), Telecentric Microlens, PGA Package, Sealed Clear Cover Glass (No Coatings),
Grade 2, Packed in Trays
Tray Configuration
Pin-Up View
Figure 37. Tray Pin-Up View
Pin 1
Tray
Position 32
Tray
Position 1
Tray
Location
Marking
Pin-Down View
Figure 38. Tray Pin-Down View
Pin 1
Tray
Position 32
Tray
Position 1
Tray
Location
Marking
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Brick Configuration
Bricks consist of 6 full trays and 1 empty tray. Each tray
contains 32 image sensors. There are a total of 192 image
sensors in the brick. The ID label is applied to the top of the
brick. Tray 1 is at the bottom of the brick and the empty tray
is at the top of the brick.
Figure 39. Brick
Strapping (2 Places)
Brick ID
Label
Tray
Sheet
Covers
Figure 40. Brick ID Label
The Brick ID is Encoded in the Bar Code.
Brick ID
Brick in Vacuum Sealed Bag
Figure 41. Sealed Brick
Brick Label
(Figure 45)
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Shipping Container
Brick Loaded in Shipping Container
Figure 42. Brick Loaded in Shipping Container
Open Shipping Container with Parts List
The parts list (see Figure 46) details information for each sensor in the brick. The parts list includes the serial number, tray
and location, and VAB value for each sensor.
Figure 43. Open Shipping Container with Parts List
Sealed Shipping Container
The Brick Label (see Figure 45) is applied to both ends of the shipping container.
Figure 44. Sealed Shipping Container
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Brick Label
Figure 45. Brick Label
Parts List
The parts list details information for each sensor in the brick. The parts list includes the serial number , tray and location, and
VAB value for each sensor. Additionally, the VAB value and serial number are encoded in the bar code.
Figure 46. Parts List
Serial Number
VAB
Position in Tray
Tray
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ON Semiconductor and the are registered trademarks of Semiconductor Components Industries, LLC (SCILLC) or its subsidiaries in the United States and/or other countries.
SCILLC owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed
at www.onsemi.com/site/pdf/Patent− Marking. pdf. S CILLC reserves the r ight to make changes w ithout furt her not ice to a ny products herein. S CILLC makes n o warranty, representation
or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and
specifically disclaims any and all l iabilit y, including without limitation special, consequent ial o r i ncident al d amages. “Typical” parameters w hich m ay b e provided in SCILLC data sheets
and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each
customer application b y c ust omer’s technical e xperts. SCILLC does not c onvey a ny license under its p atent rights nor t he r ights o f o thers. SCILLC products ar e n ot d esigned, i ntended,
or authorized for use as c omponent s i n s yst ems i nt ended f or s urgic al i m plant i nt o the body , or other applications intended to support or s ust ain life, or for any other application in which
the failure of the SCILLC product could create a situation where personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or
unauthorized application, Buyer shall indemnify and hold SCILLC an d it s officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and
expenses, and r easonable a ttorney f ees a rising o ut of, directly o r i ndirectly, any claim o f personal injury or d eath a ssociated w ith s uch u nintended o r u nauthorized u se, even if s uch c laim
alleges that SCILLC was negligent regarding the d esign or manufacture of the p art. SCILLC is a n E qual O pportunity/Af firmative Act ion Employer. This literature is subject t o a ll applicable
copyright laws and is not for resale in any manner.
P
UBLICATION ORDERING INFORMATION
N. American Technical Support: 800−282−9855 Toll Free
USA/Canada
Europe, Middle East and Africa Technical Support:
Phone: 421 33 790 2910
Japan Customer Focus Center
Phone: 81−3−5817−1050
KAI−02150/D
LITERATURE FULFILLMENT:
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P.O. Box 5163, Denver, Colorado 80217 USA
Phone: 303−675−2175 or 800−344−3860 Toll Free USA/Canada
Fax: 303−675−2176 or 800−344−3867 Toll Free USA/Canada
Email: orderlit@onsemi.com
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Order Literature: http://www.onsemi.com/orderlit
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