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Part Number FTF3020-C

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FTF3020-C
Full Frame CCD Image Sensor
Philips
Semiconductors
IMAGE SENSORS
Product specification
1999 November 22
File under Image Sensors
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1999 November
2
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
·
35mm film compatible image format (36 x 24 mm
2
)
·
6M active pixels (3072H x 2048V)
·
RGB Bayer pattern
·
Progressive scan
·
Excellent anti-blooming
·
Variable electronic shuttering
·
Square pixel structure
·
H and V binning
·
80% optical fill factor
·
High linear dynamic range (>72dB)
·
High sensitivity
·
Low dark current and fixed-pattern noise
·
Low read-out noise
·
Data rate up to 36 MHz
·
Mirrored, split and four quadrant read-out
·
Perfectly matched to visual spectrum
Description
The FTF3020-C is a full frame CCD colour image sensor designed
for professional digital photography applications, with very low dark
current and a linear dynamic range of over 12 true bits at room
temperature. The four low-noise output amplifiers, one at each corner
of the chip, make the FTF3020-C suitable for a wide range of high-
end visual light applications. With one output amplifier, a progressively
scanned image can be read out at 5 frames per second. By using
multiple outputs the frame rate increases accordingly. The device
structure is shown in figure 1.
Device structure
Optical size:
36.864 mm (H) x 24.576 mm (V)
Chip size:
39.148 mm (H) x 26.508 mm (V)
Pixel size:
12 µm x 12 µm
Active pixels:
3072 (H) x 2048 (V)
Total no. of pixels:
3120 (H) x 2060 (V)
Optical black pixels:
Left: 20 Right: 20
Timing pixels:
Left: 4
Right: 4
Dummy register cells:
Left: 7
Right: 7
Optical black lines:
Bottom: 6
Top: 6
Figure 1 - Device structure
Image Area
3072 active pixels
2048
active
lines
20
20
6 black lines
6 black lines
2060
lines
4
4
7
7
3120 cells
Output amplifier
Output register
3134 cells
G B G B
G B G B
R G R G
G B G B
G B G B
R G R G
G B G B
R G R G
G B G B
R G R G
Z
Y
W
X
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1999 November
3
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Architecture of the FTF3020-C
The optical centres of all pixels in the image section form a square
grid. The charge is generated and integrated in this section. Output
registers are located below and above the image section for read-
out. After the integration time, the image charge is shifted one line
at the time to either the upper or lower register or to both
simultaneously, depending on the read-out mode. The left and the
right half of each register can be controlled independently. This
enables either single or multiple read-out. During vertical transport,
the C3 gates separate the pixels in the register. The central C3 gates
of the lower and upper registers are part of the left half of the sensor
(W and Z quadrants respectively). Each register can be used for
vertical binning. Each register contains a summing gate at both ends
that can be used for horizontal binning (see figure 2).
OUTPUT REGISTERS
Output buffers on each corner
Number of registers
Number of dummy cells per register
Number of register cells per register
Output register horizontal transport clock pins
Capacity of each C-clock phase
Overlap capacity between neighbouring C-clocks
Output register Summing Gates
Capacity of each SG
Reset Gate clock phases
Capacity of each RG
Three-stage source follower
2
14 (2x7)
3134 (3120+14)
6 pins per register (C1..C3)
200 pF per pin
40pF
4 pins (SG)
15pF
4 pins (RG)
15pF
IMAGE SECTION
Image diagonal (active video only)
Aspect ratio
Active image width x height
Pixel width x height
Geometric fill factor
Image clock pins
Capacity of each clock phase
Number of active lines
Number of black reference lines
Number of dummy black lines
Total number of lines
Number of active pixels per line
Number of overscan (timing) pixels per line
Number of black reference pixels per line
Total number of pixels per line
44.30 mm
3:2
36.864 x 24.576 mm
2
12x12 µm
2
80%
16 pins (A1..A4)
7.5nF per pin
2048
4 (=2x2)
8 (=2x4)
2060
3072
8 (2x4)
40 (2x20)
3120
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1999 November
4
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Figure 2 - Detailed internal structure
A1, A2, A3, A4: clocks of image section
C1, C2, C3: clocks of horizontal registers
SG: summing gate
OG: output gate
RG: reset gate
RD: reset drain
OG
C1
OG
OG
One Pixel
A3
A4
A2
A3
A4
A2
A1
A2
A3
A4
A2
A3
A4
A1
A2
A3
A4
A1
A2
A3
A4
A2
A3
A4
A1
A2
A3
A1
A3
A4
A1
A1
RG
A3
A3
A4
A4
A3
A4
A2
A2
A4
A3
A2
RD
OUT_Y
A2
6 black
lines
3K image
pixels
C1
C1
SG C2
C2
C2
C1
C2
C1
C2 C1
C2
C1
C2
C2
C1
C1
C2
C1
C2
C1
C2
C1
C2
C1 SG OG
C1
C3
C1
C1
C2
C2
C2
C1
C2
C1
C2
C1
2K active
images
lines
6 black
lines
C2
C1
C2
C1
C2
C2
C1
C1
C2
C1
C2
C1
C2
RD
RG
RG
IMAGE
SG
RG
RD
OUT_X
RG
RD
C1 SG
7 dummy pixels
20 black &4 timing
columns
20 black & 4 timing
columns
7 dummy pixels
column
1
column
24 + 1
column
24 + 3K
column
24 +3K +24
OUT_Z
OUT_W
3K x 2K
FF CCD
A1
A1
A1
A1
A1
A1
A1
A1
A1
A1
A1
A1
A1
A1
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
C3
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1999 November
5
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
1
During Charge Reset it is allowed to exceed maximum rating levels (see note
5
).
2
All voltages in relation to SFS.
3
To set the VNS voltage for optimal Vertical Anti-Blooming (VAB), it should be adjustable between minimum and maximum values.
4
Three-level clock is preferred for maximum charge; the swing during vertical transport should be 4V higher than the voltage during integration.
A two level clock (typically 10V) can be used if a lower maximum charge handling capacity is allowed.
5
Charge Reset can be achieved in two ways:
· The typical A-clock low level is applied to all image clocks; for proper CR, an additional Charge Reset pulse on VNS is required (preferred).
· The typical CR level is applied to all image clocks simultaneously.
Specifications
DC CONDITIONS
2
MIN. [V]
TYPICAL [V]
MAX. [V]
MAX. [mA]
VNS
3
VPS
SFD
SFS
VCS
OG
RD
N substrate
P substrate
Source Follower Drain
Source Follower Source
Current Source
Output Gate
Reset Drain
18
1
16
0
-5
4
13
24
3
20
0
0
6.5
15.5
28
7
24
0
3
8
18
15
15
4.5
1
-
-
-
AC CLOCK LEVEL CONDITIONS
2
MIN.
TYPICAL
MAX.
UNIT
IMAGE CLOCKS:
A-clock amplitude during integration and hold
A-clock amplitude during vertical transport (duty cycle=5/8)
4
A-clock low level
Charge Reset (CR) level on A-clock
5
8
10
-5
10
14
0
-5
V
V
V
V
OUTPUT REGISTER CLOCKS:
C-clock amplitude (duty cycle during hor. transport = 3/6)
C-clock low level
Summing Gate (SG) amplitude
Summing Gate (SG) low level
4.75
2
5
3.5
10
3.5
5.25
10
V
V
V
V
OTHER CLOCKS:
Reset Gate (RG) amplitude
Reset Gate (RG) low level
Charge Reset (CR) pulse on Nsub
5
5
0
10
3
10
10
10
V
V
V
ABSOLUTE MAXIMUM RATINGS
1
MIN.
MAX.
UNIT
GENERAL:
storage temperature
ambient temperature during operation
voltage between any two gates
DC current through any clock phase (absolute value)
OUT current (no short circuit protection)
-55
-40
-20
-0.2
0
+80
+60
+20
+2.0
10
°C
°C
V
µA
mA
VOLTAGES IN RELATION TO VPS:
VNS, SFD, RD
VCS, SFS
all other pins
-0.5
-8
-5
+30
+5
+25
V
V
V
VOLTAGES IN RELATION TO VNS:
SFD, RD
VCS, SFS, VPS
all other pins
-15
-30
-30
+0.5
+0.5
+0.5
V
V
V
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1999 November
6
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Timing diagrams (for default operation)
VD: Frame pulse
CR: Charge Reset
BLC: Black Level Clamp
A1 to A4: Vertical image clocks
C1 to C3: Horizontal register clocks
SSC: Start-Stop C-clocks
SG: Summing gate
RG: Reset gate
1
Tp = 1 clock period
2
Duty cycle = 50% and phase shift of the C clocks is 120 degrees.
Figure 3 - Timing diagrams
AC CHARACTERISTICS
MIN.
TYPICAL
MAX.
UNIT
Horizontal frequency (1/Tp)
1
Vertical frequency
Charge Reset (CR) time
Rise and fall times:
image clocks (A)
register clocks (C)
2
summing gate (SG)
reset gate (RG)
10
10
3
3
3
18
50
193.7
20
5
5
5
36
100
1/6 Tp
1/6 Tp
1/6 Tp
MHz
kHz
µs
ns
ns
ns
ns
2047
2046
2048
Sensor Output
A2, A3, A4
VD
BLC
D
A1
B
B
D
1
2
3
Integration Time
Ahigh
CR
SSC
EXT. SHUTTER
H
L
SSC
A1
A2
A3
A4
CR
AHigh
VD
BLC
C1
C2
C3
SG
RG
SSC
Tp = 1 / 18MHz = 55.56ns
Pixel output sequence: 7 dummy, 20 black, 4 timing, 3072 active, 4 timing, 20 black
Line Time: 3487 x Tp = 193.7µs
Pixel Timing
Black
Dummy
*
* During AHigh = H the phiA high level is increased from 10V to 14V (This is necessary during readout only)
*
B
B
B
B
B
B
B
B
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
Tp
360
Tp
230
Tp
66
Tp
138
Tp
20
Tp
138
Tp
112
Tp
204
Tp
138
Tp
360
Tp
396
Tp
30
3127 pixels
Tp / 6
Frame Timing
Line Timing
1Tp
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1999 November
7
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Y / Div. :
10V (A1, A2, A3, A 4); 5V (SSC)
Y / Div. :
5V (C1, C2, C3); 10V (SG, RG)
Line timing
Pixel timing
SSC
A1
A2
A3
A4
C1
C2
C3
SG
RG
Figure 5 - Start horizontal readout
Figure 4 - Vertical readout
--> time
--> time
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1999 November
8
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
0
2,000
4,000
6,000
8,000
10,000
12,000
14,000
0
5
10
15
20
25
30
35
40
Performance
The test conditions for the performance characteristics are as follows:
· All values are measured using typical operating conditions.
· VNS is adjusted as low as possible while maintaining proper
Vertical Anti-Blooming.
· Sensor temperature = 60°C (333K).
· Horizontal transport frequency = 18MHz.
· Vertical transport frequency = 50kHz (unless specified otherwise).
1
Linear dynamic range is defined as the ratio of Q
lin
to read-out noise (the latter reduced by Correlated Double Sampling).
2
Charge Transfer Efficiency values are tested by evaluation and expressed as the value per gate transfer.
3
Low Pass Shading is defined as the ratio of the one-
value of an 8x8 pixels blurred image (low-pass) to the mean signal value.
4
RNU is defined as the ratio of the one-
value of the highpass image to the mean signal value at nominal light.
· Integration time = 10ms (unless specified otherwise).
· The light source is a lamp of 3200K in conjunction with neutral
density filters and a 1.7mm thick BG40 infrared cut-off filter. For
Linear Operation measurements, a temperature conversion filter
(Melles Griot type no. 03FCG261, -120 mired, thickness: 2.5mm)
is applied.
Figure 6 - Typical Linear dynamic range vs. horizontal read-out frequency and sensor temperature
LDR
Hor. Frequency (MHz)
Linear Dynamic Range
35°C
45°C
55°C
LINEAR OPERATION
MIN.
TYPICAL
MAX.
UNIT
Linear dynamic range
1
Charge Transfer Efficiency
2
vertical
Charge Transfer Efficiency
2
horizontal
Image lag
Resolution (MTF) @ 42 lp/mm
Responsivity
Quantum efficiency @ 530 nm
Low Pass Shading
3
Random Non-Uniformity (RNU)
4
VNS required for good Vertical Anti-Blooming (VAB)
Power dissipation at 2.5 frames/s
4200:1(12bit)
65
60
20
18
0.999995
0.999999
70
26
2.0
0.3
24
610
0
5
5
28
%
%
kel/lux·s
%
%
%
V
mW
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1999 November
9
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
0
5
10
15
20
25
400
450
500
550
600
650
700
0
2
4
6
8
10
12
14
16
18
20
0
10
20
30
40
50
60
70
80
90
100
Figure 8 - Quantum efficiency versus wavelength
Figure 7 - Maximum number of images/second versus integration time
Images/sec.
Integration time (ms)
Maximum Read-out Speed
Quantum efficiency (%)
Wavelength (nm)
Quantum Efficiency
1 output
2 outputs
4 outputs
R
G
B
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1999 November
10
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
1
Qmax is determined from the lowpass filtered image.
2
Qmax, shading is the maximum difference of the full-well charges of all pixels, relative to Qmax.
3
The linear full-well capacity Qlin is calculated from linearity test (see dynamic range). The evaluation test guarantees 97% linearity.
4
Charge handling capacity is the largest charge packet that can be transported through the register and read-out through the output buffer.
5
Overexposure over entire area while maintaining good Vertical Anti-Blooming (VAB). It is tested by measuring the dark line.
Figure 9 - Charge handling versus integration/transport voltage
Output Signal (k
el.)
Exposure (arbitrary units)
Charge Handling vs. Integration/Transport Voltage
10V/14V
9V/13V
8V/12V
0
100
200
300
400
500
600
1
2
3
4
5
6
LINEAR/SATURATION
MIN.
TYPICAL
MAX.
UNIT
Full-well capacity saturation level (Qmax
)
1
Full-well capacity shading (Qmax, shading
)
2
Full-well capacity linear operation (Qlin
)
3
Charge handling capacity
4
Overexposure
5
handling
240
180
500
10
350
600
200
600
50
kel.
%
kel.
kel.
x Qmax level
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1999 November
11
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
1
10
100
1000
0
10
20
30
40
50
60
1
FPN is the one-
value of the highpass image.
1
Matching of the four outputs is specified as
ACF with respect to reference measured at the operating point (Q
lin
/2).
Figure 10 - Dark current versus temperature
Dar
k Current (pA/cm
2
)
Dark Current
DARK CONDITION
MIN.
TYPICAL
MAX.
UNIT
Dark current level @ 30
°
C
Dark current level @ 60
°
C
Fixed Pattern Noise
1
(FPN) @ 60
°
C
RMS readout noise @ 9MHz bandwidth after CDS
20
0.3
15
25
30
0.6
25
30
pA/cm
2
nA/cm
2
el.
el.
OUTPUT BUFFERS
MIN.
TYPICAL
MAX.
UNIT
Conversion factor
Mutual conversion factor matching (
ACF)
1
Supply current
Bandwidth
Output impedance buffer (R
load
= 3.3k
, C
load
= 2pF)
5
7.5
0
4.5
110
400
10
2
µV/el.
µV/el.
mA
MHz
Temp. (
o
C)
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1999 November
12
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Application information
Current handling
One of the purposes of VPS is to drain the holes that are generated
during exposure of the sensor to light. Free electrons are either
transported to the VRD connection and, if excessive (from over-
exposure), free electrons are drained to VNS. No current should
flow into any VPS connection of the sensor. During high overexposure
a total current 10 to 15mA through all VPS connections together
may be expected. The PNP emitter follower in the circuit diagram
(figure 11) serves these current requirements.
VNS drains superfluous electrons as a result of overexposure. In
other words, it only sinks current. During high overexposure a total
current of 10 to 15mA through all VNS connections together may be
expected. The NPN emitter follower in the circuit diagram meets
these current requirements. The clamp circuit, consisting of the diode
and electrolytic capacitor, enables the addition of a Charge Reset
(CR) pulse on top of an otherwise stable VNS voltage. To protect the
CCD, the current resulting from this pulse should be limited. This
can be accomplished by designing a pulse generator with a rather
high output impedance.
Decoupling of DC voltages
All DC voltages (not VNS, which has additional CR pulses as
described above) should be decoupled with a 100nF decoupling
capacitor. This capacitor must be mounted as close as possible to
the sensor pin. Further noise reduction (by bandwidth limiting) is
achieved by the resistors in the connections between the sensor
and its voltage supplies. The electrons that build up the charge
packets that will reach the floating diffusions only add up to a small
current, which will flow through VRD. Therefore a large series resistor
in the VRD connection may be used.
Outputs
To limit the on-chip power dissipation, the output buffers are designed
with open source outputs. Outputs to be used should therefore be
loaded with a current source or more simply with a resistance to
GND. In order to prevent the output (which typically has an output
impedance of about 400
) from bandwidth limitation as a result of
capacitive loading, load the output with an emitter follower built from
a high-frequency transistor. Mount the base of this transistor as close
as possible to the sensor and keep the connection between the
emitter and the next stage short. The CCD output buffer can easily
be destroyed by ESD. By using this emitter follower, this danger is
suppressed; do NOT reintroduce this danger by measuring directly
on the output pin of the sensor with an oscilloscope probe. Instead,
measure on the output of the emitter follower. Slew rate limitation is
avoided by avoiding a too-small quiescent current in the emitter
follower; about 10mA should do the job. The collector of the emitter
follower should be decoupled properly to suppress the Miller effect
from the base-collector capacitance.
A CCD output load resistor of 3.3k
typically results in a bandwidth
of 110MHz. The bandwidth can be enlarged to about 130MHz by
using a resistor of 2.2k
instead, which, however, also enlarges the
on-chip power dissipation.
Device protection
The output buffers of the FTF3020-C are likely to be damaged if
VPS rises above SFD or RD at any time. This danger is most realistic
during power-on or power-off of the camera. The RD voltage should
always be lower than the SFD voltage.
Never exceed the maximum output current. This may damage the
device permanently. The maximum output current should be limited
to 10mA.
Be especially aware that the output buffers of these image sensors
are very sensitive to ESD damage.
Because of the fact that our CCDs are built on an n-type substrate,
we are dealing with some parasitic npn transistors. To avoid activation
of these transistors during switch-on and switch-off of the camera,
we recommend the application diagram of figure 11.
Unused sections
To reduce power consumption the following steps can be taken.
Connect unused output register pins (C1...C3, SG, OG) and unused
SFS pins to zero Volts.
Colour processing
In order to guarantee true colours, always use an external IR filter
type CM500(0)s, 1mm or similar. The cover glass itself is not an IR
filter.
More information
Detailed application information is provided in the application note
AN01 entitled `Camera Electronics for the mK x nK CCD Image
Sensor Family
'.
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1999 November
13
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Figure 11 - Application diagram to protect the FTF3020-C
Device Handling
An image sensor is a MOS device which can be destroyed by electro-
static discharge (ESD). Therefore, the device should be handled
with care.
Always store the device with short-circuiting clamps or on conductive
foam. Always switch off all electric signals when inserting or removing
the sensor into or from a camera (the ESD protection in the CCD
image sensor process is less effective than the ESD protection of
standard CMOS circuits).
Being a high quality optical device, it is important that the cover
glass remain undamaged. When handling the sensor, use fingercots.
When cleaning the glass we recommend using ethanol (or possibly
water). Use of other liquids is strongly discouraged:
· if the cleaning liquid evaporates too quickly, rubbing is likely to
cause ESD damage.
· the cover glass and its coating can be damaged by other liquids.
Rub the window carefully and slowly.
Dry rubbing of the window may cause electro-static charges or
scratches which can destroy the device.
BAT74
Schottky!
VPS
SFD
VRD
BC
860C
BC
850C
VNS
+
-
1uF
100nF
100nF
100nF
100nF
2mA
BC
850C
0.5-1mA
27
15
10k
CR pulse
0
0.5-1mA
VCS
VOG
10k
10k
OUT
<7pF!
keep short
<10mm!
keep short!
output for
preprocessing
BFR
92A
1k
3.3k
10mA
100nF
100nF
100nF
BAT74
BAT74
0.5-1mA
BAT74
Schottky!
100
VSFD
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1999 November
14
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Pin configuration
The FTF3020-C is mounted in a Pin Grid Array (PGA) package with
96 pins in a 20x15 grid of 52.70 x 40.00 mm
2
. The position of pin A1
(quadrant W) is marked with a gold dot on top of the package.
Figure 12 - FTF3020-C pin configuration (top view)
The image clock phases of quadrant W are internally connected to
X, and Y is connected to Z.
Symbol
Name
Pin # W
Pin # X
Pin # Y
Pin # Z
VNS
VNS
VNS
VNS
VPS
SFD
SFS
VCS
OG
RD
A1
A2
A3
A4
C1
C2
C3
SG
RG
OUT
NC
NC
NC
NC
N substrate
N substrate
N substrate
N substrate
P substrate
Source Follower Drain
Source Follower Source
Current Source
Output Gate
Reset Drain
Image Clock (Phase 1)
Image Clock (Phase 2)
Image Clock (Phase 3)
Image Clock (Phase 4)
Register Clock (Phase 1)
Register Clock (Phase 2)
Register Clock (Phase 3)
Summing Gate
Reset Gate
Output
Not Connected
Not Connected
Not Connected
Not Connected
A1
A5
C2
G1
A2
B2
D2
C1
B3
D1
B5
A3
A4
B4
F2
F1
G2
E1
E2
B1
I1
I2
H1
H2
U1
U5
S2
M1
U2
T2
R2
S1
T3
R1
T5
U3
U4
T4
N2
N1
M2
P1
P2
T1
K1
K2
L1
L2
U10
U6
S9
M10
U9
T9
R9
S10
T8
R10
T6
U8
U7
T7
N9
N10
M9
E10
P9
T10
K10
K9
L10
L9
A10
A6
C9
G10
A9
B9
D9
C10
B8
D10
B6
A8
A7
B7
F9
F10
G9
P10
E9
B10
I10
I9
H10
H9
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
S
T
U
10
9
8
7
6
5
4
3
2
1
TOP
Y
Z
X
W
FTF3020-C
background image
1999 November
15
Philips Semiconductors
Product specification
Full Frame CCD Image Sensor
FTF3020-C
Package information
Figure 13 - Mechanical drawing of the PGA package of the FTF3020-C
A is the center of the image area.
Position of A:
26.35
± 0.15 to left edge of package
20.00 ± 0.15 to upper edge of package
1.7 ± 0.15 to bottom of package
Angle of rotation: less than ± 1°
Sensor flatness: < 20 µm (P-V)
Cover glass: Corning 7059
Thickness of cover glass: 1 ± 0.05
Refractive index: n
d
= 1.53
Double sided AR coating < 1% (430-660 nm) reflection
All drawing units are in mm
35.56
±
0.20
48.26
±
0.27
Chip - bottom package 1.7 ±0.15
1.4 / 100
COVER GLASS
SENSOR CRYSTAL
Chip - cover glass 1.3 ±0.20
EPOXY GLUE
A
TOP VIEW
INDEX
MARK
PIN 1
52.7
±
0.53
26.35
±
0.15
1.27
±
0.15
20
±
0.15
0.46
±
0.05
(2.54)
STAND-OFF PIN
COVER GLASS
40
±
0.40
BOTTOM VIEW
Cover glass 1.0 ±0.05
Image sensor chip
4.57
±
0.15
Top cover glass to top chip 2.4 ±0.25
background image
Order codes
The sensors can be ordered using the following codes:
You can contact the Image Sensors division of Philips
Semiconductors at the following address:
Philips Semiconductors
Image Sensors
Internal Postbox WAG-05
Prof. Holstlaan 4
5656 AA Eindhoven
The Netherlands
phone
+31 - 40 - 27 44 400
fax
+31 - 40 - 27 44 090
www.semiconductors.philips.com/imagers/
Philips reser
v
es the r
ight to change an
y inf
o
r
mation contained herein without notice
.
All inf
o
r
mation fur
nished b
y
Philips is b
elie
v
ed to be accur
ate
.
© Philips Electronics N.V
.
1999
9922 157 37411
Philips
Semiconductors
FTF3020-C sensors
Description
Quality Grade
Order Code
FTF3020-C/TG
FTF3020-C/EG
FTF3020-C/IG
FTF3020-C/HG
Test grade
Economy grade
Industrial grade
High grade
9922 157 37431
9922 157 37451
9922 157 37421
9922 157 37411

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