Sony ICX279AL Datasheet

ICX279AL

Diagonal 4.5mm (Type 1/4) CCD Image Sensor for CCIR B/W Video Cameras

Description

The ICX279AL is an interline CCD solid-state
image sensor suitable for CCIR B/W video cameras
with a diagonal 4.5mm (Type 1/4) system. Compared
with the current product ICX209AL, basic
characteristics such as sensitivity, smear and
dynamic range are improved drastically from visible
light region to near infrared light region through the
adoption of EXview HAD CCDTM technology.

This chip features a field period readout system and
an electronic shutter with variable charge-storage time.

The package is a 10mm-square 14-pin DIP (Plastic).

Features

• Sensitivity in near infrared light region

(+5dB compared with the ICX209AL, λ = 945nm)

• High sensitivity (+6dB compared with the ICX209AL, no IR cut filter)

• Low smear (–20dB compared with the ICX209AL)

• High D range (+2dB compared with the ICX209AL)

• Horizontal register: 3.3 to 5V drive

• Reset gate: 3.3 to 5V drive

• No voltage adjustment

(Reset gate and substrate bias are not adjusted.)

• High resolution and low smear

• Excellent antiblooming characteristics

• Continuous variable-speed shutter

• Recommended range of exit pupil distance: –20 to –100mm

14 pin DIP (Plastic)

V

3

Pin 8

H

Optical black position

(T op View)

Pin 1

40

2

12

Device Structure

• Interline CCD image sensor

• Image size: Diagonal 4.5mm (Type 1/4)

• Number of effective pixels: 752 (H) × 582 (V) approx. 440K pixels

• Total number of pixels: 795 (H) × 596 (V) approx. 470K pixels

• Chip size: 4.43mm (H) × 3.69mm (V)

• Unit cell size: 4.85µm (H) × 4.65µm (V)

• Optical black: Horizontal (H) direction : Front 3 pixels, rear 40 pixels

Vertical (V) direction : Front 12 pixels, rear 2 pixels

• Number of dummy bits: Horizontal 22

Vertical 1 (even fields only)

• Substrate material: Silicon

TM

∗

EXview HAD CCD is a trademark of Sony Corporation.

EXview HAD CCD is a CCD that drastically improves light efficiency by including near infrared light region as a basic structure of

HAD (Hole-Accumulation-Diode) sensor.

Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by
any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the
operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.

– 1 –

E00Z52

Block Diagram and Pin Configuration

(Top View)

OUT

V

GND

7 6 5 4 3 2 1

Vertical Register

8 9 10 11 12 13 14

DD

V

GND

1

NC

Vφ

Horizontal Register

L

V

φSUB

2

Vφ

RG

3

4

Vφ

Vφ

Note)

Note) : Photo sensor

1

2

Hφ

Hφ

Pin Description

Pin No. Symbol Description Pin No. Symbol Description

ICX279AL

1

Vφ4

2

Vφ3

3

Vφ2

4

Vφ1

5

NC

6

GND

7

VOUT

Vertical register transfer clock
Vertical register transfer clock
Vertical register transfer clock
Vertical register transfer clock

GND
Signal output

Absolute Maximum Ratings

VDD, VOUT, RG – φSUB
Vφ1, Vφ3 – φSUB

Against φSUB

Vφ2, Vφ4, VL – φSUB
Hφ1, Hφ2, GND – φSUB
VDD, VOUT, RG – GND

Against GND

Vφ1, Vφ2, Vφ3, Vφ4 – GND
Hφ1, Hφ2 – GND
Vφ1, Vφ3 – VL

Against VL

Vφ2, Vφ4, Hφ1, Hφ2, GND – VL

Voltage difference between vertical clock input pins
Between input clock
pins

Hφ1 – Hφ2

Hφ1, Hφ2 – Vφ4
Storage temperature

Item

8

9
10
11
12
13
14

VDD
GND
φSUB
VL
RG
Hφ1
Hφ2

Supply voltage
GND
Substrate clock
Protective transistor bias
Reset gate clock
Horizontal register transfer clock
Horizontal register transfer clock

Ratings Unit Remarks
–40 to +8
–50 to +15
–50 to +0.3
–40 to +0.3
–0.3 to +18
–10 to +18
–10 to +6
–0.3 to +28
–0.3 to +15
to +15
–5 to +5
–13 to +13
–30 to +80

V
V
V
V
V
V
V
V
V
V
V
V

°C

1

∗

Operating temperature

1

∗

+24V (Max.) when clock width < 10µs, clock duty factor < 0.1%.

– 2 –

–10 to +60

°C

Bias Conditions

ICX279AL

Item
Supply voltage
Protective transistor bias
Substrate clock
Reset gate clock

1

∗

VL setting is the VVL voltage of the ver tical transfer clock waveform, or the same power supply as the VL

Symbol

VDD
VL

φSUB
φRG

Min.

14.55 15.45

15.0

1

∗

2

∗

2

∗

Unit RemarksTyp. Max.

V

power supply for the V driver should be used.

2

∗

Do not apply a DC bias to the substrate clock and reset gate clock pins, because a DC bias is generated
within the CCD.

DC Characteristics

Item
Supply current

Symbol4Min. Unit RemarksTyp. Max.

IDD

mA6

Clock V olta ge Conditions

V
V

Waveform
diagram

1
2

Remarks

VVH = (VVH1 + VVH2)/2

Item

Readout clock voltage

Symbol

VVT
VVH1, VVH2

Min.

14.55
–0.05

Typ.

15.0
0

Max. Unit

15.45

0.05

Vertical transfer clock
voltage

Horizontal transfer
clock voltage

Reset gate clock
voltage

Substrate clock voltage

VVH3, VVH4
VVL1, VVL2,

VVL3, VVL4
VφV
VVH3 – VVH
VVH4 – VVH
VVHH
VVHL
VVLH
VVLL
VφH
VHL

VφRG
VRGLH – VRGLL

VRGL – VRGLm
VφSUB

–0.2
–8.0

6.3

–0.25
–0.25

3.0

–0.05

3.0

21.0

0

–7.0

7.0

3.3
0

3.3

22.0

0.05
–6.5

8.05

0.1

0.1

0.3

0.3

0.3

0.3

5.25

0.05

5.5

0.4

0.5

23.5

V
V
V

V
V
V
V
V
V
V
V

V
V

V
V

2
2

VVL = (VVL3 + VVL4)/2

2

VφV = VVHn – VVLn (n = 1 to 4)
2
2
2

High-level coupling
2

High-level coupling
2

Low-level coupling
2

Low-level coupling
3
3

Input through 0.1µF

4

capacitance
4

Low-level coupling
4

Low-level coupling
5

– 3 –

Clock Equivalent Circuit Constant

ICX279AL

Item Min.

Capacitance between vertical transfer clock
and GND

Capacitance between vertical transfer clocks

Capacitance between horizontal transfer clock
and GND

Capacitance between horizontal transfer clocks
Capacitance between reset gate clock and GND
Capacitance between substrate clock and GND
Vertical transfer clock series resistor
Vertical transfer clock ground resistor
Horizontal transfer clock series resistor
Reset gate clock series resistor

Vφ

Vφ

1

2

Symbol
CφV1, CφV3
CφV2, CφV4
CφV12, CφV34
CφV23, CφV41
CφV13
CφV24

CφH1, CφH2
CφHH

CφRG
CφSUB
R1, R2, R3, R4
RGND
RφH
RφRG

Typ. Max.

1200

680
220
150

82
75

22
36

5

180

82
15
12
51

Unit Remarks

pF
pF
pF
pF
pF
pF

pF
pF

pF
pF

Ω
Ω
Ω
Ω

Cφ

Vφ

Cφ

V24

4

Cφ

Cφ

V12

V1

V4

R

Cφ

GND

V34

Cφ

Cφ

V2

V3

Cφ

Cφ

R

V23

V13

R

2

3

Vφ

Rφ

H

Hφ

1

Cφ

H1

3

Cφ

HH

Cφ

Rφ

H

Hφ

2

H2

R

1

Cφ

V41

R

4

Horizontal transfer clock equivalent circuitVertical transfer clock equivalent circuit

Rφ

RGφ

RG

Cφ

RG

Reset gate clock equivalent circuit

– 4 –

Drive Clock Waveform Conditions

(1) Readout clock waveform

100%

90%

V

VT

10%

0%

tr tf

twh

(2) Vertical transfer clock waveform

Vφ1 Vφ3

ICX279AL

φM

φM

2

0V

VVH1

VVL

Vφ2 Vφ4

VVHL

VVH2

VVHH

VVHH

VVLL

VVL1

VVHH

VVH

VVHL

VVLH

VVHH

VVHL

VVL3

VVH

VVHL

VVHL

VVHH

VVH

VVH3

VVHL

VVL

VVHL

VVHH

VVH4

VVHH

VVH

VVLH

VVLL

VVHH

VVHL

VVLL

VVL

V

VH = (VVH1 + VVH2)/2

VVL = (VVL3 + V VL4)/2
VφV = VVHn – VVLn (n = 1 to 4)

VVL2

VVLH

– 5 –

VVL4

VVLH

VVLL

VVL

(3) Horizontal transfer clock waveform

tr twh tf

90%

10%

V

HL

(4) Reset gate clock waveform

twl

Vφ

ICX279AL

H

twl

twhtr tf

VRGH

Vφ

RG

VRGL

RG waveform

VRGLH

V

RGLL

VRGLm

Hφ1 waveform

H/2 [V]

Vφ

Point A

VRGLH is the maximum value and VRGLL is the minimum value of the coupling waveform during the period from
Point A in the above diagram until the rising edge of RG. In addition, VRGL is the average value of VRGLH and
VRGLL.

VRGL = (VRGLH + VRGLL)/2

Assuming VRGH is the minimum value during the interval twh, then:

VφRG = VRGH – VRGL

Negative overshoot level during the falling edge of RG is VRGLm.

(5) Substrate clock waveform

100%

90%

10%

V

(A bias generated within the CCD)

SUB

0%

Vφ

SUB

tr tftwh

– 6 –

φM

φM

2