AD9954YSVZREEL7 - ANALOG DEVICES - Datasheet.Directory

REV. 0

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AD9948

10-Bit CCD Signal Processor with

Precision Timing

™

Core

FUNCTIONAL BLOCK DIAGRAM

CLAMP

DOUT

CCDIN

REFT REFB

INTERNAL

REGISTERS

6dB TO 42dB

SYNC

GENERATOR

SDATASCK

HBLK

VGA

AD9948

PRECISION

TIMING

CORE

10-BIT

ADC

REF

INTERNAL

CLOCKS

PxGA

CDS

HORIZONTAL

DRIVERS

H1–H4

HD VD

CLI

CLP/PBLK

0dB TO 18dB

FEATURES

Correlated Double Sampler (CDS)

0 dB to 18 dB Pixel Gain Amplifier (

PxGA

®)

6 dB to 42 dB 10-Bit Variable Gain Amplifier (VGA)

10-Bit 25 MSPS A/D Converter

Black Level Clamp with Variable Level Control

Complete On-Chip Timing Driver

Precision Timing Core with 800 ps Resolution

On-Chip 3 V Horizontal and RG Drivers

40-Lead LFCSP Package

APPLICATIONS

Digital Still Cameras

High Speed Digital Imaging Applications

GENERAL DESCRIPTION

The AD9948 is a highly integrated CCD signal processor for

digital still camera applications. Specified at pixel rates of up to

25 MHz, the AD9948 consists of a complete analog front end

with A/D conversion, combined with a programmable timing

driver. The Precision Timing core allows adjustment of high

speed clocks with 800 ps resolution.

The analog front end includes black level clamping, CDS, PxGA,

VGA, and a 25 MHz 10-bit A/D converter. The timing driver

provides the high speed CCD clock drivers for RG and H1–H4.

Operation is programmed using a 3-wire serial interface.

Packaged in a space-saving 40-lead LFCSP package, the

AD9948 is specified over an operating temperature range of

–20°C to +85°C.

AD9948* PRODUCT PAGE QUICK LINKS

Last Content Update: 02/23/2017

COMPARABLE PARTS

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DOCUMENTATION

Data Sheet

•AD9948: 10-Bit CCD Signal Processor with

Precision

Timing

™ Core Data Sheet

REFERENCE MATERIALS

Technical Articles

•MS-2210: Designing Power Supplies for High Speed ADC

DESIGN RESOURCES

•AD9948 Material Declaration

•PCN-PDN Information

•Quality And Reliability

•Symbols and Footprints

DISCUSSIONS

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SAMPLE AND BUY

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TECHNICAL SUPPORT

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number.

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REV. 0–2–

AD9948–SPECIFICATIONS

DIGITAL SPECIFICATIONS

Parameter Symbol Min Typ Max Unit

LOGIC INPUTS

High Level Input Voltage V

2.1 V

Low Level Input Voltage V

0.6 V

High Level Input Current I

10 µA

Low Level Input Current I

10 µA

Input Capacitance C

10 pF

LOGIC OUTPUTS

High Level Output Voltage, I

= 2 mA V

2.2 V

Low Level Output Voltage, I

= 2 mA V

0.5 V

CLI INPUT

High Level Input Voltage

(TCVDD/2 + 0.5 V) V

IH–CLI

1.85 V

Low Level Input Voltage V

IL–CLI

0.85 V

RG AND H-DRIVER OUTPUTS

High Level Output Voltage

(RGVDD – 0.5 V and HVDD – 0.5 V) V

2.2 V

Low Level Output Voltage V

0.5 V

Maximum Output Current (Programmable) 30 mA

Maximum Load Capacitance 100 pF

Specifications subject to change without notice.

GENERAL SPECIFICATIONS

Parameter Min Typ Max Unit

TEMPERATURE RANGE

Operating –20 +85 °C

Storage –65 +150 °C

MAXIMUM CLOCK RATE 25 MHz

POWER SUPPLY VOLTAGE

AVDD, TCVDD (AFE, Timing Core) 2.7 3.0 3.6 V

HVDD (H1–H4 Drivers) 2.7 3.0 3.6 V

RGVDD (RG Driver) 2.7 3.0 3.6 V

DRVDD (D0–D9 Drivers) 2.7 3.0 3.6 V

DVDD (All Other Digital) 2.7 3.0 3.6 V

POWER DISSIPATION

25 MHz, HVDD = RGVDD = 3 V, 100 pF H1–H4 Loading*220 mW

Total Shutdown Mode 1 mW

*The total power dissipated by the HVDD supply may be approximated using the equation

Total HVDD Power C HVDD Pixel Frequency HVDD Number of H Outputs Used

LOAD

=×× ×× −()()

Reducing the H-loading, using only two of the outputs, and/or using a lower HVDD supply will reduce the power dissipation.

Specifications subject to change without notice.

(TMIN to TMAX, AVDD = DVDD = DRVDD = HVDD = RGVDD = 2.7 V, CL = 20 pF, unless otherwise noted.)

REV. 0

AD9948

–3–

ANALOG SPECIFICATIONS

Parameter Min Typ Max Unit Notes

CDS

Gain 0 dB

Allowable CCD Reset Transient*500 mV

Max Input Range before Saturation*1.0 V p-p

Max CCD Black Pixel Amplitude*±50 mV

PIXEL GAIN AMPLIFIER (PxGA)

Gain Control Resolution 256 Steps

Gain Monotonicity

Min Gain 0 dB

Max Gain 18 dB

VARIABLE GAIN AMPLIFIER (VGA)

Max Input Range 1.0 V p-p

Max Output Range 2.0 V p-p

Gain Control Resolution 1024 Steps

Gain Monotonicity Guaranteed

Gain Range

Min Gain (VGA Code 0) 6 dB

Max Gain (VGA Code 1023) 42 dB

BLACK LEVEL CLAMP

Clamp Level Resolution 256 Steps

Clamp Level Measured at ADC output

Min Clamp Level (0) 0 LSB

Max Clamp Level (255) 63.75 LSB

A/D CONVERTER

Resolution 10 Bits

Differential Nonlinearity (DNL) –1.0 ±0.5 +1.0 LSB

No Missing Codes Guaranteed

Full-Scale Input Voltage 2.0 V

VOLTAGE REFERENCE

Reference Top Voltage (REFT) 2.0 V

Reference Bottom Voltage (REFB) 1.0 V

SYSTEM PERFORMANCE Specifications include entire

signal chain

VGA Gain Accuracy

Min Gain (Code 0) 5.0 5.5 6.0 dB

Max Gain (Code 1023) 40.5 41.5 42.5 dB

Peak Nonlinearity, 500 mV Input Signal 0.2 % 12 dB gain applied

Total Output Noise 0.25 LSB rms AC grounded input, 6 dB

gain applied

Power Supply Rejection (PSR) 50 dB Measured with step change

on supply

*Input signal characteristics defined as follows:

50mV MAX

OPTICAL BLACK PIXEL

500mV TYP

RESET TRANSIENT

1V MAX

INPUT SIGNAL RANGE

Specifications subject to change without notice.

(TMIN to TMAX, AVDD = DVDD = 3.0 V, fCLI = 25 MHz, Typical Timing Specifications,

unless otherwise noted.)

REV. 0–4–

AD9948

TIMING SPECIFICATIONS

Parameter Symbol Min Typ Max Unit

MASTER CLOCK (CLI) (See Figure 4)

CLI Clock Period t

CLI

40 ns

CLI High/Low Pulsewidth t

ADC

16 20 24 ns

Delay from CLI to Internal Pixel

Period Position t

CLIDLY

6ns

CLPOB Pulsewidth (Programmable)*t

COB

220 Pixels

SAMPLE CLOCKS (See Figure 6)

SHP Rising Edge to SHD Rising Edge t

17 20 ns

DATA OUTPUTS (See Figures 7a and 7b)

Output Delay From Programmed Edge t

6ns

Pipeline Delay 11 Cycles

SERIAL INTERFACE

Maximum SCK Frequency f

SCLK

10 MHz

SL to SCK Setup Time t

10 ns

SCK to SL Hold Time t

10 ns

SDATA Valid to SCK Rising Edge Setup t

10 ns

SCK Falling Edge to SDATA Valid Hold t

10 ns

SCK Falling Edge to SDATA Valid Read t

10 ns

*Minimum CLPOB pulsewidth is for functional operation only. Wider typical pulses are recommended to achieve low noise clamp reference.

Specifications subject to change without notice.

(CL = 20 pF, fCLI = 25 MHz, Serial Timing in Figure 3, unless otherwise noted.)

ABSOLUTE MAXIMUM RATINGS*

With

Parameter Respect To Min Max Unit

AVDD, TCVDD AVSS –0.3 +3.9 V

HVDD, RGVDD HVSS, RGVSS –0.3 +3.9 V

DVDD, DRVDD DVSS, DRVSS –0.3 +3.9 V

Any VSS Any VSS –0.3 +0.3 V

Digital Outputs DRVSS –0.3 DRVDD + 0.3 V

CLPOB/PBLK, HBLK DVSS –0.3 DVDD + 0.3 V

SCK, SL, SDATA DVSS –0.3 DVDD + 0.3 V

RG RGVSS –0.3 RGVDD + 0.3 V

H1–H4 HVSS –0.3 HVDD + 0.3 V

REFT, REFB, CCDIN AVSS –0.3 AVDD + 0.3 V

Junction Temperature 150 °C

Lead Temperature (10 sec) 300 °C

*Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress

rating only; functional operation of the device at these or any other conditions above those listed in the operational sections

of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect

device reliability.

CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily

accumulate on the human body and test equipment and can discharge without detection. Although

the AD9948 features proprietary ESD protection circuitry, permanent damage may occur on

devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are

recommended to avoid performance degradation or loss of functionality.

ORDERING GUIDE

Temperature Package Package

Model Range Description Option

AD9948KCP –20°C to +85°CLFCSP CP-40

AD9948KCPRL –20°C to +85°CLFCSP CP-40

AD9948KCPZ*–20°C to +85°CLFCSP CP-40

AD9948KCPZRL*–20°C to +85°CLFCSP CP-40

*This is a lead free product.

THERMAL CHARACTERISTICS

Thermal Resistance

40-Lead LFCSP Package

␪

= 27°C/W*

*␪

is measured using a 4-layer PCB with the exposed paddle

soldered to the board.

REV. 0

AD9948

–5–

PIN FUNCTION DESCRIPTIONS

Pin No. Mnemonic Type*Description

2–4 D0–D2 DO Data Outputs (D0 is LSB)

5DRVSS P Digital Driver Ground

6DRVDD P Digital Driver Supply

7–13 D3–D9 DO Data Outputs (D9 is MSB)

14 H1 DO CCD Horizontal Clock 1

15 H2 DO CCD Horizontal Clock 2

16 HVSS P H1–H4 Driver Ground

17 HVDD P H1–H4 Driver Supply

18 H3 DO CCD Horizontal Clock 3

19 H4 DO CCD Horizontal Clock 4

20 RGVSS P RG Driver Ground

21 RG DO CCD Reset Gate Clock

22 RGVDD P RG Driver Supply

23 TCVSS P Analog Ground for Timing Core

24 TCVDD P Analog Supply for Timing Core

25 CLI DI Master Clock Input

26 AVDD P Analog Supply for AFE

27 CCDIN AI Analog Input for CCD Signal (Connect through Series 0.1 µF Capacitor)

28 AVSS P Analog Ground for AFE

29 REFT AO Reference Top Decoupling (Decouple with 1.0 µF to AVSS)

30 REFB AO Reference Bottom Decoupling (Decouple with 1.0 µF to AVSS)

31 SL DI 3-Wire Serial Load

32 SDI DI 3-Wire Serial Data Input

33 SCK DI 3-Wire Serial Clock

34 VD DI Vertical Sync Pulse

35 HD DI Horizontal Sync Pulse

36 DVSS P Digital Ground

37 DVDD P Digital Supply

38 HBLK DI Optional HBLK Input

39 CLP/PBLK DO CLPOB or PBLK Output

1, 40 NC Not Internally Connected

*Type: AI = Analog Input, AO = Analog Output, DI = Digital Input, DO = Digital Output, P = Power.

PIN CONFIGURATION

TOP VIEW

AD9948

PIN 1

IDENTIFIER

30 REFB

29 REFT

28 AVSS

27 CCDIN

26 AVDD

25 CLI

24 TCVDD

23 TCVSS

22 RGVDD

21 RG

NC 1

(LSB) D0 2

D1 3

D2 4

DRVSS 5

DRVDD 6

D3 7

D4 8

D5 9

D6 10

40 NC

39 CLP/PBLK

38 HBLK

37 DVDD

36 DVSS

35 HD

34 VD

33 SCK

32 SDI

31 SL

D7 11

D8 12

(MSB) D9 13

H1 14

H2 15

HVSS 16

HVDD 17

H3 18

H4 19

RGVSS 20

REV. 0–6–

AD9948

EQUIVALENT CIRCUITS

AVDD

AVSS AVSS

Circuit 1. CCDIN (Pin 27)

AVDD

AVSS

330

CLI

25k

1.4V

Circuit 2. CLI (Pin 25)

DVSS DRVDD

DVSS DRVSS

DATA

THREE-

STATE DOUT

Circuit 3. Data Outputs D0–D9 (Pins 2–4, 7–13)

DVDD

DVSS

330

Circuit 4. Digital Inputs (Pins 31–35, 38)

HVDD or RGVDD

HVSS or RGVSS

DATA

ENABLE OUTPUT

Circuit 5. H1–H4 and RG (Pins 14, 15, 18, 19, 21)

TERMINOLOGY

Differential Nonlinearity (DNL)

An ideal ADC exhibits code transitions that are exactly 1 LSB

apart. DNL is the deviation from this ideal value. Thus every

code must have a finite width. No missing codes guaranteed to

10-bit resolution indicates that all 1024 codes, respectively,

must be present over all operating conditions.

Peak Nonlinearity

Peak nonlinearity, a full signal chain specification, refers to the

peak deviation of the output of the AD9948 from a true straight

line. The point used as zero scale occurs 0.5 LSB before the

first code transition. Positive full scale is defined as a level 1 LSB

and 0.5 LSB beyond the last code transition. The deviation is

measured from the middle of each particular output code to the

true straight line. The error is then expressed as a percentage of

the 2 V ADC full-scale signal. The input signal is always appro-

priately gained up to fill the ADC’s full-scale range.

Total Output Noise

The rms output noise is measured using histogram techniques.

The standard deviation of the ADC output codes is calculated in

LSB, and represents the rms noise level of the total signal chain

at the specified gain setting. The output noise can be converted

to an equivalent voltage, using the relationship

LSB (ADC full scale/ codes)=

where n is the bit resolution of the ADC. For the AD9948,

1LSB is approximately 1.95 mV.

Power Supply Rejection (PSR)

The PSR is measured with a step change applied to the supply

pins. The PSR specification is calculated from the change in the

data outputs for a given step change in the supply voltage.

REV. 0

Typical Performance Characteristics–AD9948

–7–

–1.0

01000

400

200 600 800

–0.5

0.5

1.0

ADC OUTPUT CODE

DNL (LSB)

TPC 1. Typical DNL

VGA GAIN CODE (LSB)

01000

400

OUTPUT NOISE (LSB)

200

2.5

600 800

5.0

7.5

TPC 2. Output Noise vs. VGA Gain

SAMPLE RATE (MHz)

250

200

100

POWER DISSIPATION (mW)

150

175

225

VDD = 3.3V

125

275

VDD = 3.0V

VDD = 2.7V

TPC 3. Power Curves

REV. 0–8–

AD9948

SYSTEM OVERVIEW

CCD

SERIAL

INTERFACE

DOUT

DIGITAL IMAGE

PROCESSING

ASIC

V-DRIVER

HD, VD

CLI

V1–Vx, VSG1–VSGx, SUBCK

H1–H4, RG

CCDIN

AD9948

INTEGRATED

AFE + TD

Figure 1. Typical Application

Figure 1 shows the typical system application diagram for the

AD9948. The CCD output is processed by the AD9948’s AFE

circuitry, which consists of a CDS, a PxGA, a VGA, a black level

clamp, and an A/D converter. The digitized pixel information is

sent to the digital image processor chip, where all postprocessing

and compression occurs. To operate the CCD, CCD timing

parameters are programmed into the AD9948 from the image

processor through the 3-wire serial interface. From the system

master clock, CLI, provided by the image processor, the AD9948

generates the high speed CCD clocks and all internal AFE clocks.

All AD9948 clocks are synchronized with VD and HD. All of

the AD9948’s horizontal pulses (CLPOB, PBLK, and HBLK)

are programmed and generated internally.

The H-drivers for H1–H4 and RG are included in the AD9948,

allowing these clocks to be connected directly to the CCD.

H-drive voltage of 3 V is supported in the AD9948.

Figure 2a shows the horizontal and vertical counter dimensions

for the AD9948. All internal horizontal clocking is programmed

using these dimensions to specify line and pixel locations.

MAXIMUM FIELD DIMENSIONS

12-BIT HORIZONTAL = 4096 PIXELS MAX

12-BIT VERTICAL = 4096 LINES MAX

Figure 2a. Vertical and Horizontal Counters

MAX VD LENGTH IS 4095 LINES

CLI

MAX HD LENGTH IS 4095 PIXELS

Figure 2b. Maximum VD/HD Dimensions

REV. 0

AD9948

–9–

SERIAL INTERFACE TIMING

All of the internal registers of the AD9948 are accessed through

a 3-wire serial interface. Each register consists of an 8-bit address

and a 24-bit data-word. Both the 8-bit address and 24-bit data-

word are written starting with the LSB. To write to each register,

a 32-bit operation is required, as shown in Figure 3a. Although

many registers are less than 24 bits wide, all 24 bits must be

written for each register. If the register is only 16 bits wide, then

the upper eight bits are don’t cares and may be filled with zeros

during the serial write operation. If fewer than 24 bits are written,

the register will not be updated with new data.

Figure 3b shows a more efficient way to write to the registers by

using the AD9948’s address auto-increment capability. Using

this method, the lowest desired address is written first, followed

by multiple 24-bit data-words. Each new 24-bit data-word will

be written automatically to the next highest register address. By

eliminating the need to write each 8-bit address, faster register

loading is achieved. Address auto-increment may be used start-

ing with any register location, and may be used to write to as

few as two registers or as many as the entire register space.

COMPLETE REGISTER LISTING

All addresses and default values are expressed in hexadecimal.

All registers are VD/HD updated as shown in Figure 3a, except

for the registers indicated in Table I, which are SL updated.

Table I. SL-Updated Registers

OPRMODE AFE Operation Modes

CTLMODE AFE Control Modes

SW_RESET Software Reset Bit

TGCORE _RSTB Reset Bar Signal for Internal TG Core

PREVENTUPDATE Prevents Update of Registers

VDHDEDGE VD/HD Active Edge

FIELDVAL Resets Internal Field Pulse

HBLKRETIME Retimes the HBLK to Internal Clock

CLPBLKOUT CLP/BLK Output Pin Select

CLPBLKEN Enables CLP/BLK Output Pin

H1CONTROL H1/H2 Polarity Control

RGCONTROL H1 Positive Edge Location

DRVCONTROL H1 Negative Edge Location

SAMPCONTROL H1 Drive Current

DOUTPHASE H2 Drive Current

SDATA A0 A1 A2 A4 A5 A6 A7 D0 D1 D2 D3 D21 D22 D23

SCK

NOTES

1. INDIVIDUAL SDATA BITS ARE LATCHED ON SCK RISING EDGES.

2. ALL 32 BITS MUST BE WRITTEN: 8 BITS FOR ADDRESS AND 24 BITS FOR DATA.

3. IF THE REGISTER LENGTH IS <24 BITS, THEN DON’T CARE BITS MUST BE USED TO COMPLETE THE 24-BIT DATA LENGTH.

4. NEW DATA IS UPDATED AT EITHER THE SL RISING EDGE OR AT THE HD FALLING EDGE AFTER THE NEXT VD FALLING EDGE.

5. VD/HD UPDATE POSITION MAY BE DELAYED TO ANY HD FALLING EDGE IN THE FIELD USING THE UPDATE REGISTER.

tDH

tLS tLH

tDS

SL UPDATED VD/HD UPDATED

...

8-BIT ADDRESS 24-BIT DATA

1 32234567891011 12 30 31

Figure 3a. Serial Write Operation

SDATA A0 A1 A2 A4 A5 A6 A7 D0 D1 D22 D23

SCK

NOTES

1. MULTIPLE SEQUENTIAL REGISTERS MAY BE LOADED CONTINUOUSLY.

2. THE FIRST (LOWEST ADDRESS) REGISTER ADDRESS IS WRITTEN, FOLLOWED BY MULTIPLE 24-BIT DATA-WORDS.

3. THE ADDRESS WILL AUTOMATICALLY INCREMENT WITH EACH 24-BIT DATA-WORD (ALL 24 BITS MUST BE WRITTEN).

4. SL IS HELD LOW UNTIL THE LAST DESIRED REGISTER HAS BEEN LOADED.

5. NEW DATA IS UPDATED AT EITHER THE SL RISING EDGE OR AT THE HD FALLING EDGE AFTER THE NEXT VD FALLING EDGE.

D0 D1 D22 D23 D0

...

DATA FOR STARTING

D2D1

...

1 322345678910 31 3433 5655 58

57 59

Figure 3b. Continuous Serial Write Operation

REV. 0–10–

AD9948

Table II. AFE Register Map

Data Bit Default

Address Content Value Name Description

00 [11:0] 4 OPRMODE AFE Operation Modes. (See Table VIII.)

01 [9:0] 0 VGAGAIN VGA Gain.

02 [7:0] 80 CLAMP LEVEL Optical Black Clamp Level.

03 [11:0] 4 CTLMODE AFE Control Modes. (See Table IX.)

04 [17:0] 0 PxGA GAIN01 PxGA Gain Registers for Color 0 [8:0] and Color 1 [17:9].

05 [17:0] 0 PxGA GAIN23 PxGA Gain Registers for Color 2 [8:0] and Color 3 [17:9].

Table III. Miscellaneous Register Map

Data Bit Default

Address Content Value Name Description

10 [0] 0 SW_RST Software Reset.

1 = Reset all registers to default, then self-clear back to 0.

11 [0] 0 OUT_CONTROL Output Control.

0 = Make all dc outputs inactive.

12 [0] 0 TGCORE_RSTB Timing Core Reset Bar.

0 = Reset TG core.

1 = Resume operation.

13 [11:0] 0 UPDATE Serial Update.

Sets the line (HD) within the field to update serial data.

14 [0] 0 PREVENTUPDATE Prevents the update of the VD-Updated Registers.

1 = Prevent update.

15 [0] 0 VDHDEDGE VD/HD Active Edge.

0 = Falling edge triggered.

1 = Rising edge triggered.

16 [1:0] 0 FIELDVAL Field Value Sync.

0 = Next Field 0.

1 = Next Field 1.

2/3 = Next Field 2.

17 [0] 0 HBLKRETIME Retime HBLK to Internal H1 Clock.

Preferred setting is 1. Setting to 1 will add one cycle delay to HBLK

toggle positions.

18 [1:0] 0 CLPBLKOUT CLP/BLK Pin Output Select.

0 = CLPOB.

1 = PBLK.

2 = HBLK.

3 = Low.

19 [0] 1 CLPBLKEN Enable CLP/BLK Output.

1 = Enable.

1A [0] 0 TEST MODE Internal Test Mode.

Should always be set low.

REV. 0

AD9948

–11–

Table IV. CLPOB Register Map

Data Bit Default

Address Content Value (Hex) Name Description

20 [3:0] F CLPOBPOL Start Polarities for CLPOB Sequences 0, 1, 2, and 3.

21 [23:0] FFFFFF CLPOBTOG_0 Sequence 0. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

22 [23:0] FFFFFF CLPOBTOG_1 Sequence 1. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

23 [23:0] FFFFFF CLPOBTOG_2 Sequence 2. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

24 [23:0] FFFFFF CLPOBTOG_3 Sequence 3. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

0CLPOBSCP0 CLPOB Sequence-Change-Position 0 (Hard-Coded to 0).

25 [7:0] 0 CLPOBSPTR CLPOB Sequence Pointers for Region 0 [1:0], 1 [3:2], 2 [5:4], 3 [7:6].

26 [11:0] FFF CLPOBSCP1 CLPOB Sequence-Change-Position 1.

27 [11:0] FFF CLPOBSCP2 CLPOB Sequence-Change-Position 2.

28 [11:0] FFF CLPOBSCP3 CLPOB Sequence-Change-Position 3.

Table V. PBLK Register Map

Data Bit Default

Address Content Value (Hex) Name Description

30 [3:0] F PBLKPOL Start Polarities for PBLK Sequences 0, 1, 2, and 3.

31 [23:0] FFFFFF PBLKTOG_0 Sequence 0. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

32 [23:0] FFFFFF PBLKTOG_1 Sequence 1. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

33 [23:0] FFFFFF PBLKTOG_2 Sequence 2. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

34 [23:0] FFFFFF PBLKTOG_3 Sequence 3. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

0PBLKSCP0 PBLK Sequence-Change-Position 0 (Hard-Coded to 0).

35 [7:0] 0 PBLKSPTR PBLK Sequence Pointers for Region 0 [1:0], 1 [3:2], 2 [5:4], 3 [7:6].

36 [11:0] FFF PBLKSCP1 PBLK Sequence-Change-Position 1.

37 [11:0] FFF PBLKSCP2 PBLK Sequence-Change-Position 2.

38 [11:0] FFF PBLKSCP3 PBLK Sequence-Change-Position 3.

REV. 0–12–

AD9948

Table VI. HBLK Register Map

Data Bit Default

Address Content Value (Hex) Name Description

40 [0] 0 HBLKDIR HBLK Internal/External.

0 = Internal.

1 = External.

41 [0] 0 HBLKPOL HBLK External Active Polarity.

0 = Active Low.

1 = Active High.

42 [0] 1 HBLKEXTMASK HBLK External Masking Polarity.

0 = Mask H1 Low.

1 = Mask H1High.

43 [3:0] F HBLKMASK HBLK Internal Masking Polarity.

0 = Mask H1 Low.

1 = Mask H1 High.

44 [23:0] FFFFFF HBLKTOG12_0 Sequence 0. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

45 [23:0] FFFFFF HBLKTOG34_0 Sequence 0. Toggle Position 3 [11:0] and Toggle Position 4 [23:12].

46 [23:0] FFFFFF HBLKTOG56_0 Sequence 0. Toggle Position 5 [11:0] and Toggle Position 6 [23:12].

47 [23:0] FFFFFF HBLKTOG12_1 Sequence 1. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

48 [23:0] FFFFFF HBLKTOG34_1 Sequence 1. Toggle Position 3 [11:0] and Toggle Position 4 [23:12].

49 [23:0] FFFFFF HBLKTOG56_1 Sequence 1. Toggle Position 5 [11:0] and Toggle Position 6 [23:12].

4A [23:0] FFFFFF HBLKTOG12_2 Sequence 2. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

4B [23:0] FFFFFF HBLKTOG34_2 Sequence 2. Toggle Position 3 [11:0] and Toggle Position 4 [23:12].

4C [23:0] FFFFFF HBLKTOG56_2 Sequence 2. Toggle Position 5 [11:0] and Toggle Position 6 [23:12].

4D [23:0] FFFFFF HBLKTOG12_3 Sequence 3. Toggle Position 1 [11:0] and Toggle Position 2 [23:12].

4E [23:0] FFFFFF HBLKTOG34_3 Sequence 3. Toggle Position 3 [11:0] and Toggle Position 4 [23:12].

4F [23:0] FFFFFF HBLKTOG56_3 Sequence 3. Toggle Position 5 [11:0] and Toggle Position 6 [23:12].

0HBLKSCP0 HBLK Sequence-Change-Position 0 (Hard-coded to 0).

50 [7:0] 0 HBLKSPTR HBLK Sequence Pointers for Region 0 [1:0], 1 [3:2], 2 [5:4], 3 [7:6].

51 [11:0] FFF HBLKSCP1 HBLK Sequence-Change-Position 1.

52 [11:0] FFF HBLKSCP2 HBLK Sequence-Change-Position 2.

53 [11:0] FFF HBLKSCP3 HBLK Sequence-Change-Position 3.

Table VII. H1–H2, RG, SHP, SHD Register Map

Data Bit Default

Address Content Value Name Description

60 [12:0] 01001 H1CONTROL H1 Signal Control. Polarity [0] (0 = Inversion, 1 = No Inversion).

H1 Positive Edge Location [6:1].

H1 Negative Edge Location [12:7].

61 [12:0] 00801 RGCONTROL RG Signal Control. Polarity [0] (0 = Inversion, 1 = No Inversion).

RG Positive Edge Location [6:1].

RG Negative Edge Location [12:7].

62 [14:0] 0 DRVCONTROL Drive Strength Control for H1 [2:0], H2 [5:3], H3 [8:6], H4 [11:9], and

RG [14:12].

Drive Current Values: 0 = Off, 1 = 4.3 mA, 2 = 8.6 mA, 3 = 12.9 mA,

4 = 17.2 mA, 5 = 21.5 mA, 6 = 25.8 mA, 7 = 30.1 mA.

63 [11:0] 00024 SAMPCONTROL SHP/SHD Sample Control. SHP Sampling Location [5:0].

SHD Sampling Location [11:6].

64 [5:0] 0 DOUTPHASE DOUT Phase Control.

REV. 0

AD9948

–13–

Table VIII. AFE Operation Register Detail

Data Bit Default

Address Content Value Name Description

00 [1:0] 0 PWRDOWN 0 = Normal Operation.

1 = Reference Standby.

2/3 = Total Power-Down.

[2] 1 CLPENABLE 0 = Disable OB Clamp.

1 = Enable OB Clamp.

[3] 0 CLPSPEED 0 = Select Normal OB Clamp Settling.

1 = Select Fast OB Clamp Settling.

[4] 0 FASTUPDATE 0 = Ignore VGA Update.

1 = Very Fast Clamping when VGA Is Updated.

[5] 0 PBLK_LVL DOUT Value during PBLK.

0 = Blank to Zero.

1 = Blank to Clamp Level.

[7:6] 0 TEST MODE Test Operation Only. Set to zero.

[8] 0 DCBYP 0 = Enable DC Restore Circuit.

1 = Bypass DC Restore Circuit during PBLK.

[9] 0 TESTMODE Test Operation Only. Set to zero.

[11:10] 0 CDSGAIN Adjustment of CDS Gain.

0 = 0 dB.

01= –2 dB.

10 = –4 dB.

11 = 0 dB.

Table IX. AFE Control Register Detail

Data Bit Default

Address Content Value Name Description

04 [1:0] 0 COLORSTEER 0 = Off.

1 = Progressive.

2 = Interlaced.

3 = Three Field.

[2] 1 PXGAENABLE 0 = Disable PxGA.

1 = Enable PxGA.

[3] 0 DOUTDISABLE 0 = Data Outputs Are Driven.

1 = Data Outputs Are Three-Stated.

[4] 0 DOUTLATCH 0 = Latch Data Outputs with DOUT Phase.

1 = Output Latch Transparent.

[5] 0 GRAYENCODE 0 = Binary Encode Data Outputs.

1= Gray Encode Data Outputs.

REV. 0–14–

AD9948

PRECISION TIMING HIGH SPEED TIMING GENERATION

The AD9948 generates flexible high speed timing signals using

the Precision Timing core. This core is the foundation for gener-

ating the timing used for both the CCD and the AFE; the reset

gate RG, horizontal drivers H1–H4, and the SHP/SHD sample

clocks. A unique architecture makes it routine for the system

designer to optimize image quality by providing precise control

over the horizontal CCD readout and the AFE correlated

double sampling.

Timing Resolution

The Precision Timing core uses a 1× master clock input (CLI)

as a reference. This clock should be the same as the CCD pixel

clock frequency. Figure 4 illustrates how the internal timing core

divides the master clock period into 48 steps or edge positions.

Therefore, the edge resolution of the Precision Timing core is

CLI

/48). For more information on using the CLI input, refer to

the Applications Information section.

High Speed Clock Programmability

Figure 5 shows how the high speed clocks, RG, H1–H4, SHP,

and SHD, are generated. The RG pulse has programmable rising

and falling edges, and may be inverted using the polarity control.

The horizontal clocks H1 and H3 have programmable rising and

falling edges, and polarity control. The H2 and H4 clocks are

always inverses of H1 and H3, respectively. Table X summarizes

the high speed timing registers and their parameters.

Each edge location setting is 6 bits wide, but only 48 valid edge

locations are available. Therefore, the register values are mapped

into four quadrants, with each quadrant containing 12 edge

locations. Table XI shows the correct register values for the

corresponding edge locations.

NOTES

1. PIXEL CLOCK PERIOD IS DIVIDED INTO 48 POSITIONS, PROVIDING FINE EDGE RESOLUTION FOR HIGH SPEED CLOCKS.

2. THERE IS A FIXED DELAY FROM THE CLI INPUT TO THE INTERNAL PIXEL PERIOD POSITIONS (tCLIDLY = 6 ns TYP).

P[0] P[48] = P[0]

P[12] P[24] P[36]

1 PIXEL

PERIOD

...

CLI

tCLIDLY

POSITION

Figure 4. High Speed Clock Resolution From CLI Master Clock Input

H1/H3

H2/H4

CCD SIGNAL

(1) (2)

(3)

(4)

(5) (6)

PROGRAMMABLE CLOCK POSITIONS:

1. RG RISING EDGE

2. RG FALLING EDGE

3. SHP SAMPLE LOCATION

4. SHD SAMPLE LOCATION

5. H1/H3 RISING EDGE POSITION

6. H1/H3 FALLING EDGE POSITION (H2/H4 ARE INVERSE OF H1/H3)

Figure 5. High Speed Clock Programmable Locations

Table X. H1CONTROL, RGCONTROL, DRVCONTROL, and SAMPCONTROL Register Parameters

Parameter Length Range Description

Polarity 1b High/Low Polarity Control for H1/H3 and RG (0 = No Inversion, 1 = Inversion).

Positive Edge 6b 0–47 Edge Location Positive Edge Location for H1/H3 and RG.

Negative Edge 6b 0–47 Edge Location Negative Edge Location for H1/H3 and RG.

Sample Location 6b 0–47 Sample Location Sampling Location for SHP and SHD.

Drive Control 3b 0–7 Current Steps Drive Current for H1–H4 and RG Outputs, 0–7 Steps of 4.1 mA Each.

DOUT Phase 6b 0–47 Edge Location Phase Location of Data Outputs with Respect to Pixel Period.

REV. 0

AD9948

–15–

Table XI. Precision Timing Edge Locations

Quadrant Edge Location (Decimal) Register Value (Decimal) Register Value (Binary)

I0 to 11 0 to 11 000000 to 001011

II 12 to 23 16 to 27 010000 to 011011

III 24 to 35 32 to 43 100000 to 101011

IV 36 to 47 48 to 59 110000 to 111011

H-Driver and RG Outputs

In addition to the programmable timing positions, the AD9948

features on-chip output drivers for the RG and H1–H4 outputs.

These drivers are powerful enough to directly drive the CCD

inputs. The H-driver and RG driver current can be adjusted

for optimum rise/fall time into a particular load by using the

DRVCONTROL register (Address x062). The DRVCONTROL

adjustable in 4.1 mA increments. The minimum setting of 0 is

equal to OFF or three-state, and the maximum setting of 7 is

equal to 30.1 mA.

As shown in Figure 6, the H2/H4 outputs are inverses of H1/H3.

The internal propagation delay resulting from the signal inversion

is less than l ns, which is significantly less than the typical rise

time driving the CCD load. This results in a H1/H2 crossover

voltage at approximately 50% of the output swing. The crossover

voltage is not programmable.

Digital Data Outputs

The AD9948 data output phase is programmable using the

DOUTPHASE register (Address x064). Any edge from 0 to 47

may be programmed, as shown in Figure 7a. The pipeline delay

for the digital data output is shown in Figure 7b.

FIXED CROSSOVER VOLTAGE

H1/H3 H2/H4

H2/H4

H1/H3

RISE

Figure 6. H-Clock Inverse Phase Relationship

NOTES

1. DIGITAL OUTPUT DATA (DOUT) PHASE IS ADJUSTABLE WITH RESPECT TO THE PIXEL PERIOD.

2. WITHIN ONE CLOCK PERIOD, THE DATA TRANSITION CAN BE PROGRAMMED TO ANY OF THE 48 LOCATIONS.

P[0] P[48] = P[0]

CLI

1 PIXEL PERIOD

P[12] P[24] P[36]

DOUT

tOD

Figure 7a. Digital Output Phase Adjustment

NOTES

DEFAULT TIMING VALUES ARE SHOWN: SHDLOC = 0, DOUT PHASE = 0.

HIGHER VALUES OF SHD AND/OR DOUTPHASE WILL SHIFT DOUT TRANSITION TO THE RIGHT, WITH RESPECT TO CLI LOCATION.

DOUT

CCDIN

CLI

SHD

(INTERNAL)

N N+1 N+2 N+12N+11N+10N+9N+8N+7N+6N+5N+4

N+3 N+13

N–13 N–3N–4N–5N–6N–7N–8N–9N–10N–11

N–12 N–2 N–1 N+1

SAMPLE PIXEL N

PIPELINE LATENCY = 11 CYCLES

tCLIDLY

N–1

Figure 7b. Pipeline Delay for Digital Data Output

REV. 0–16–

AD9948

HORIZONTAL CLAMPING AND BLANKING

The AD9948’s horizontal clamping and blanking pulses are

fully programmable to suit a variety of applications. Individual

sequences are defined for each signal, which are then organized

into multiple regions during image readout. This allows the dark

pixel clamping and blanking patterns to be changed at each

stage of the readout to accommodate different image transfer

timing and high speed line shifts.

Individual CLPOB and PBLK Sequences

The AFE horizontal timing consists of CLPOB and PBLK, as

shown in Figure 8. These two signals are independently pro-

grammed using the parameters shown in Table XII. The start

polarity, first toggle position, and second toggle position are

fully programmable for each signal. The CLPOB and PBLK

signals are active low, and should be programmed accordingly.

Up to four individual sequences can be created for each signal.

Individual HBLK Sequences

The HBLK programmable timing shown in Figure 9 is similar

to CLPOB and PBLK. However, there is no start polarity con-

trol. Only the toggle positions are used to designate the start and

the stop positions of the blanking period. Additionally, there is a

polarity control, HBLKMASK, which designates the polarity of

the horizontal clock signals H1–H4 during the blanking period.

Setting HBLKMASK high will set H1 = H3 = low and H2 =

H4 = high during the blanking, as shown in Figure 10. Up to

four individual sequences are available for HBLK.

(3)(2)

(1)

CLPOB

PBLK

. . .

PROGRAMMABLE SETTINGS:

1. START POLARITY (CLAMP AND BLANK REGION ARE ACTIVE LOW)

2. FIRST TOGGLE POSITION

3. SECOND TOGGLE POSITION

. . .

ACTIVE ACTIVE

Figure 8. Clamp and Preblank Pulse Placement

(2)

(1)

HBLK

. . .

PROGRAMMABLE SETTINGS:

1. FIRST TOGGLE POSITION = START OF BLANKING

2. SECOND TOGGLE POSITION = END OF BLANKING

. . .

BLANK BLANK

Figure 9. Horizontal Blanking (HBLK) Pulse Placement

Table XII. CLPOB and PBLK Individual Sequence Parameters

Parameter Length Range Description

Polarity 1b High/Low Starting Polarity of Clamp and PBLK Pulses for Sequences 0–3.

Toggle Position 1 12b 0–4095 Pixel Location First Toggle Position within the Line for Sequences 0–3.

Toggle Position 2 12b 0–4095 Pixel Location Second Toggle Position within the Line for Sequences 0–3.

Table XIII. HBLK Individual Sequence Parameters

Parameter Length Range Description

HBLKMASK 1b High/Low Masking Polarity for H1 for Sequences 0–3 (0 = H1 Low, 1 = H1 High).

Toggle Position 1 12b 0–4095 Pixel Location First Toggle Position within the Line for Sequences 0–3.

Toggle Position 2 12b 0–4095 Pixel Location Second Toggle Position within the Line for Sequences 0–3.

Toggle Position 3 12b 0–4095 Pixel Location Third Toggle Position within the Line for Sequences 0–3.

Toggle Position 4 12b 0–4095 Pixel Location Fourth Toggle Position within the Line for Sequences 0–3.

Toggle Position 5 12b 0–4095 Pixel Location Fifth Toggle Position within the Line for Sequences 0–3.

Toggle Position 6 12b 0–4095 Pixel Location Sixth Toggle Position within the Line for Sequences 0–3.

REV. 0

AD9948

–17–

HBLK

. . .

THE POLARITY OF H1 DURING BLANKING IS PROGRAMMABLE (H2 IS OPPOSITE POLARITY OF H1).

. . .

H1/H3

H2/H4

. . .

Figure 10. HBLK Masking Control

HBLK

SPECIAL H-BLANK PATTERN IS CREATED USING MULTIPLE HBLK TOGGLE POSITIONS.

H1/H3

H2/H4

TOG1 TOG2 TOG3 TOG4 TOG5 TOG6

Figure 11. Generating Special HBLK Patterns

GENERATING SPECIAL HBLK PATTERNS

Six toggle positions are available for HBLK. Normally, only

two of the toggle positions are used to generate the standard

HBLK interval. However, the additional toggle positions may be

used to generate special HBLK patterns, as shown in Figure 11.

The pattern in this example uses all six toggle positions to

generate two extra groups of pulses during the HBLK inter-

val. By changing the toggle positions, different patterns can

be created.

Horizontal Sequence Control

The AD9948 uses sequence change positions (SCPs) and sequence

pointers (SPTRs) to organize the individual horizontal sequences.

Up to four SCPs are available to divide the readout into four

separate regions, as shown in Figure 12. The SCP 0 is always hard-

coded to Line 0, and SCP1–SCP3 are register programmable.

During each region bounded by the SCP, the SPTR registers

designate which sequence is used by each signal. CLPOB, PBLK,

and HBLK each have a separate set of SCPs. For example,

CLPOBSCP1 will define Region 0 for CLPOB, and in that region,

any of the four individual CLPOB sequences may be selected with

the CLPOBSPTR register. The next SCP defines a new region,

and in that region each signal can be assigned to a different

individual sequence. The sequence control registers are sum-

marized in Table XIV.

External HBLK Signal

The AD9948 can also be used with an external HBLK signal. Set-

ting the HBLKDIR register (Address x040) to high will disable the

internal HBLK signal generation. The polarity of the external

signal is specified using the HBLKPOL register, and the mask-

ing polarity of H1 is specified using the HBLKMASK register.

Table XV summarizes the register values when using an external

HBLK signal.

Table XIV. Horizontal Sequence Control Parameters for CLPOB, PBLK, and HBLK

SCP 12b 0–4095 Line Number CLOB/PBLK/HBLK SCP to Define Horizontal Regions 0–3.

SPTR 2b 0–3 Sequence Number Sequence Pointer for Horizontal Regions 0–3.

REV. 0–18–

AD9948

UP TO FOUR INDIVIDUAL HORIZONTAL CLAMP AND BLANKING REGIONS MAY BE

PROGRAMMED WITHIN A SINGLE FIELD, USING THE SEQUENCE CHANGE POSITIONS.

SEQUENCE CHANGE OF POSITION 1

SEQUENCE CHANGE OF POSITION 2

SEQUENCE CHANGE OF POSITION 3

SINGLE FIELD (1 VD INTERVAL)

CLAMP AND PBLK SEQUENCE REGION 0

SEQUENCE CHANGE OF POSITION 0

(V-COUNTER = 0)

CLAMP AND PBLK SEQUENCE REGION 3

CLAMP AND PBLK SEQUENCE REGION 2

CLAMP AND PBLK SEQUENCE REGION 1

Figure 12. Clamp and Blanking Sequence Flexibility

Table XV. External HBLK Register Parameters

HBLKDIR 1b High/Low Specifies HBLK Internally Generated or Externally Supplied.

1 = External.

HBLKPOL 1b High/Low External HBLK Active Polarity.

0 = Active Low.

1 = Active High.

HBLKEXTMASK 1b High/Low External HBLK Masking Polarity.

0 = Mask H1 Low.

1 = Mask H1 High.

000 1 12111 0 031100

012345678910111214150123

023

H-COUNTER

RESET

NOTES

1. INTERNAL H-COUNTER IS RESET SEVEN CLI CYCLES AFTER THE HD FALLING EDGE (WHEN USING VDHDEDGE = 0).

2. TYPICAL TIMING RELATIONSHIP: CLI RISING EDGE COINCIDES WITH HD FALLING EDGE.

3. PxGA STEERING IS SYNCHRONIZED WITH THE RESET OF THE INTERNAL H-COUNTER (MOSAIC SEPARATE MODE IS SHOWN).

XXXXXXX

PxGA GAIN

CLI

XXXXXXX

H-COUNTER

(PIXEL COUNTER) X

Figure 13. H-Counter Synchronization

H-COUNTER SYNCHRONIZATION

The H-Counter reset occurs seven CLI cycles following the HD

falling edge. The PxGA steering is synchronized with the reset

of the internal H-Counter (see Figure 13).

REV. 0

AD9948

–19–

POWER-UP PROCEDURE

VDD

(INPUT)

SERIAL

WRITES

(OUTPUT)

1 H

ODD FIELD EVEN FIELD

...

DIGITAL

OUTPUTS

CLOCKS ACTIVE WHEN OUT_CONTROL REGISTER IS

UPDATED AT VD/HD EDGE

H1/H3, RG

H2/H4

PWR

CLI

(INPUT)

(OUTPUT)

...

Figure 14. Recommended Power-Up Sequence

Recommended Power-Up Sequence

When the AD9948 is powered up, the following sequence is

recommended (refer to Figure 14 for each step):

1. Turn on the power supplies for the AD9948.

2. Apply the master clock input, CLI, VD, and HD.

3. Although the AD9948 contains an on-chip power-on reset, a

software reset of the internal registers is recommended. Write

a 1 to the SW_RST register (Address x010), which will reset

all the internal registers to their default values. This bit is

self-clearing and will automatically be reset back to 0.

4. The Precision Timing core must be reset by writing a 0 to the

TGCORE_RSTB register (Address x012) followed by writing

a l to the TGCORE_RSTB register. This will start the internal

timing core operation.

5. Write a 1 to the PREVENTUPDATE register (Address x014).

This will prevent the updating of the serial register data.

6. Write to the desired registers to configure high speed timing

and horizontal timing.

7. Write a 1 to the OUT_CONTROL register (Address x011).

This will allow the outputs to become active after the next

VD/HD rising edge.

8. Write a 0 to the PREVENTUPDATE register (Address x014).

This will allow the serial information to be updated at next

VD/HD falling edge.

The next VD/HD falling edge allows register updates to occur,

including OUT_CONTROL, which enables all clock outputs.

REV. 0–20–

AD9948

6dB ~ 42dB

CCDIN

DIGITAL

FILTER

CLPOB

DC RESTORE

OPTICAL BLACK

CLAMP

10-BIT

ADC

VGA

DAC

CLAMP LEVEL

VGA GAIN

CDS

INTERNAL

VREF

2V FULL SCALE

0dB ~ 18dB

PRECISION

TIMING

GENERATION

SHP SHD

PxGA

1.5V

OUTPUT

DATA

LATCH

REFTREFB

DOUT

PHASE

V-H

TIMING

GENERATION

SHP SHD

DOUT

PHASE CLPOB PBLK

PBLK

1.0V 2.0V

DOUT

AD9948

PxGA GAIN

REGISTERS

0dB, –2dB, –4dB

1.0F 1.0F

1.0F

Figure 15. Analog Front End Functional Block Diagram

ANALOG FRONT END DESCRIPTION AND OPERATION

The AD9948 signal processing chain is shown in Figure 15. Each

processing step is essential in achieving a high quality image from

the raw CCD pixel data.

DC Restore

To reduce the large dc offset of the CCD output signal,

adcrestore circuit is used with an external 0.1 µF series cou-

pling capacitor. This restores the dc level of the CCD signal to

approximately 1.5 V to be compatible with the 3 V supply voltage

of the AD9948.

Correlated Double Sampler

The CDS circuit samples each CCD pixel twice to extract the

video information and reject low frequency noise. The timing

shown in Figure 5 illustrates how the two internally generated

CDS clocks, SHP and SHD, are used to sample the reference

level and the CCD signal level, respectively. The placement of

the SHP and SHD sampling edges is determined by the setting

of the SAMPCONTROL register located at Address 0x63.

Placement of these two clock signals is critical in achieving the

best performance from the CCD.

The gain in the CDS is fixed at 0 dB by default. Using Bits D10

and D11 in the AFE operation register, the gain may be reduced

to –2 dB or –4 dB. This will allow the AD9948 to accept an input

signal of greater than 1 V p-p. See Table VIII for register details.

Table XVI. Adjustable CDS Gain

Operation Register Bits

D11 D10 CDS Gain Max CDS Input

00 0 dB 1.0 V p-p

01 –2 dB 1.2 V p-p

10 –4 dB 1.6 V p-p

11 0 dB 1.0 V p-p

PxGA

The PxGA provides separate gain adjustment for the individual

color pixels. A programmable gain amplifier with four separate

values, the PxGA has the capability to multiplex its gain value on

a pixel-to-pixel basis (see Figure 16). This allows lower output

color pixels to be gained up to match higher output color pixels.

Also, the PxGA may be used to adjust the colors for white bal-

ance, reducing the amount of digital processing that is needed.

The four different gain values are switched according to the color

steering circuitry. Three different color steering modes for differ-

ent types of CCD color filter arrays are programmable in the AFE

CTLMODE register at Address 0x03 (see Figures 18a to 18c for

timing examples). For example, progressive steering mode accom-

modates the popular Bayer arrangement of red, green, and blue

filters (see Figure 17a).

COLOR

STEERING

CONTROL

4:1

MUX

GAIN0

GAIN1

GAIN2

GAIN3

PxGA

PxGA STEERING

MODE

SELECTION

PxGA GAIN

REGISTERS

CONTROL

BITS D0–D1

SHP/SHD

VGA

CDS

Figure 16. PxGA Block Diagram

REV. 0

AD9948

–21–

LINE0 GAIN0, GAIN1, GAIN0, GAIN1, ...

LINE1

LINE2

GAIN2, GAIN3, GAIN2, GAIN3, ...

GAIN0, GAIN1, GAIN0, GAIN1, ...

COLOR STEERING MODE:

PROGRESSIVE

Gb B

CCD: PROGRESSIVE BAYER

Gb B

Gb B Gb B

Figure 17a. CCD Color Filter Example—Progressive Scan

The same Bayer pattern can also be interlaced, and the interlaced

mode should be used with this type of CCD (see Figure 17b).

The color steering performs the proper multiplexing of the R,

G, and B gain values (loaded into the PxGA gain registers), and

is synchronized by the user with vertical (VD) and horizontal

(HD) sync pulses. For timing information, see Figure 18b.

LINE0 GAIN0, GAIN1, GAIN0, GAIN1, ...

LINE1

LINE2

GAIN0, GAIN1, GAIN0, GAIN1, ...

Gb GbBB

LINE0 GAIN2, GAIN3, GAIN2, GAIN3, ...

LINE1

LINE2

GAIN2, GAIN3, GAIN2, GAIN3, ...

COLOR STEERING MODE:

INTERLACED

Gb GbBB

EVEN FIELD

ODD FIELD

CCD: INTERLACED BAYER

Figure 17b. CCD Color Filter Example—Interlaced Readout

A third type of readout uses the Bayer pattern divided into three

different readout fields. The three-field mode should be used

with this type of CCD (see Figure 17c). The color steering

performs the proper multiplexing of the R, G, and B gain values

(loaded into the PxGA gain registers), and is synchronized by

the user with vertical (VD) and horizontal (HD) sync pulses.

For timing information, see Figure 18c.

LINE0 GAIN0, GAIN1, GAIN0, GAIN1, ...

LINE1

LINE2

GAIN2, GAIN3, GAIN2, GAIN3, ...

GAIN0, GAIN1, GAIN0, GAIN1, ...

LINE0 GAIN2, GAIN3, GAIN2, GAIN3, ...

LINE1

LINE2

GAIN0, GAIN1, GAIN0, GAIN1, ...

GAIN2, GAIN3, GAIN2, GAIN3, ...

COLOR STEERING MODE:

THREE FIELD

Gb GbBB

FIRST FIELD

SECOND FIELD

CCD: 3-FIELD READOUT

LINE0 GAIN0, GAIN1, GAIN0, GAIN1, ...

LINE1

LINE2

GAIN2, GAIN3, GAIN2, GAIN3, ...

GAIN0, GAIN1, GAIN0, GAIN1, ...

THIRD FIELD

Gb GbBB

Figure 17c. CCD Color Filter Example—Three-Field Readout

REV. 0–22–

AD9948

22033 11

NOTES

1. VD FALLING EDGE WILL RESET THE PxGA GAIN REGISTER STEERING TO 0101 LINE.

2. HD FALLING EDGES WILL ALTERNATE THE PxGA GAIN REGISTER STEERING BETWEEN 0101 AND 2323 LINES.

3. FIELDVAL IS ALWAYS RESET TO 0 ON VD FALLING EDGES.

110XX

PxGA GAIN

FIELDVAL

FIELDVAL = 0

022033 11

110

000

FIELDVAL = 0

Figure 18a. PxGA Color Steering—Progressive Mode

00 311 22

NOTES

1. FIELDVAL = 0 (START OF FIRST FIELD) WILL RESET THE PxGA GAIN REGISTER STEERING TO 0101 LINE.

2. FIELDVAL = 1 (START OF SECOND FIELD) WILL RESET THE PxGA GAIN REGISTER STEERING TO 2323 LINE.

3. HD FALLING EDGES WILL RESET THE PxGA GAIN REGISTER STEERING TO EITHER 0 (FIELDVAL = 0) OR 2 (FIELDVAL = 1).

4. FIELDVAL WILL TOGGLE BETWEEN 0 AND 1 ON EACH VD FALLING EDGE.

110XX

PxGA GAIN

FIELDVAL

FIELDVAL = 0

31100 00

332

211

FIELDVAL = 1 FIELDVAL = 0

Figure 18b. PxGA Color Steering—Interlaced Mode

22 333 22

NOTES

1. FIELDVAL = 0 (START OF FIRST FIELD) WILL RESET THE PxGA GAIN REGISTER STEERING TO 0101 LINE.

2. FIELDVAL = 1 (START OF SECOND FIELD) WILL RESET THE PxGA GAIN REGISTER STEERING TO 2323 LINE.

2. FIELDVAL = 2 (START OF THIRD FIELD) WILL RESET THE PxGA GAIN REGISTER STEERING TO 0101 LINE.

3. HD FALLING EDGES WILL ALTERNATE THE PxGA GAIN REGISTER STEERING BETWEEN 0101 AND 2323 LINES.

4. FIELDVAL WILL INCREMENT AT EACH VD FALLING EDGE, REPEATING THE 0...1...2...0...1...2 PATTERN.

110XX

PxGA GAIN

FIELDVAL

FIELDVAL = 0

31100 22

001

133

FIELDVAL = 1 FIELDVAL = 2

Figure 18c. PxGA Color Steering—Three-Field Mode

REV. 0

AD9948

–23–

The PxGA gain for each of the four channels is variable from 0 dB

to 18 dB in 512 steps, specified using the PxGA GAIN01 and

PxGA GAIN23 registers. The PxGA gain curve is shown in

Figure 19. The PxGA GAIN01 registers contains nine bits each

for PxGA Gain0 and Gain1, and the PxGA GAIN23 registers

contains nine bits each for PxGA Gain2 and Gain3.

PxGA GAIN REGISTER CODE

PxGA GAIN (dB)

64 128 192 256 320 384 448 511

Figure 19. PxGA Gain Curve

Variable Gain Amplifier

The VGA stage provides a gain range of 6 dB to 42 dB, program-

mable with 10-bit resolution through the serial digital interface.

The minimum gain of 6 dB is needed to match a 1 V input signal

with the ADC full-scale range of 2 V. When compared to 1 V

full-scale systems, the equivalent gain range is 0 dB to 36 dB.

The VGA gain curve follows a linear-in-dB characteristic. The

exact VGA gain can be calculated for any gain register value by

using the equation

Gain dB Code dB()(. )=×+0 0351 6

where the code range is 0 to 1023.

There is a restriction on the maximum amount of gain that can

be applied to the signal. The PxGA can add as much as 18 dB,

and the VGA is capable of providing up to 42 dB. However, the

maximum total gain from the PxGA and VGA is restricted to

42 dB. If the registers are programmed to specify a total gain

higher than 42 dB, the total gain will be clipped at 42 dB.

VGA GAIN REGISTER CODE

VGA GAIN (dB)

127 255 383 511 639 767 895 1023

Figure 20. VGA Gain Curve (PxGA Not Included)

A/D Converter

The AD9948 uses a high performance ADC architecture, opti-

mized for high speed and low power. Differential nonlinearity

(DNL) performance is typically better than 0.5 LSB. The ADC

uses a 2 V input range. See TPC 1 and TPC 2 for typical linearity

and noise performance plots for the AD9948.

Optical Black Clamp

The optical black clamp loop is used to remove residual offsets

in the signal chain and to track low frequency variations in the

CCD’s black level. During the optical black (shielded) pixel

interval on each line, the ADC output is compared with a fixed

black level reference, selected by the user in the clamp level register.

The value can be programmed between 0 LSB and 63.75 LSB

in 256 steps. The resulting error signal is filtered to reduce noise,

and the correction value is applied to the ADC input through a

D/A converter. Normally, the optical black clamp loop is turned

on once per horizontal line, but this loop can be updated more

slowly to suit a particular application. If external digital clamping

is used during the postprocessing, the AD9948 optical black

clamping may be disabled using Bit D2 in the OPRMODE register.

When the loop is disabled, the clamp level register may still be

used to provide programmable offset adjustment.

The CLPOB pulse should be placed during the CCD’s optical

black pixels. It is recommended that the CLPOB pulse duration

be at least 20 pixels wide to minimize clamp noise. Shorter

pulsewidths may be used, but clamp noise may increase and the

ability to track low frequency variations in the black level will be

reduced. See the Horizontal Clamping and Blanking and the

Applications Information sections for timing examples.

Digital Data Outputs

The AD9948 digital output data is latched using the DOUT

phase register value, as shown in Figure 15. Output data timing is

shown in Figure 7. It is also possible to leave the output latches

transparent, so that the data outputs are valid immediately from

the A/D converter. Programming the AFE control register Bit D4

to a 1 will set the output latches transparent. The data outputs

can also be disabled (three-stated) by setting the AFE control

The data output coding is normally straight binary, but the

coding my be changed to gray coding by setting the AFE

control register Bit D5 to a 1.

REV. 0–24–

AD9948

ANALOG

SUPPLY

SERIAL

INTERFACE

CCD SIGNAL

VD/HD/HBLK INPUTS

CLP/BLK OUTPUT

DRIVER

SUPPLY

RG DRIVER

SUPPLY

H DRIVER

SUPPLY

MASTER CLOCK INPUT

ANALOG

SUPPLY

DATA

OUTPUTS

H1–H4

TOP VIEW

AD9948

PIN 1

IDENTIFIER

30 REFB

29 REFT

28 AVSS

27 CCDIN

26 AVDD

25 CLI

24 TCVDD

23 TCVSS

22 RGVDD

21 RG

NC 1

D1 3

D2 4

DRVDD 6

D3 7

D4 8

D5 9

D6 10

40 NC

39 CLP/PBLK

38 HBLK

37 DVDD

36 DVSS

35 HD

34 VD

33 SCK

32 SDI

31 SL

D7 11

D8 12

(MSB) D9 13

H1 14

H2 15

HVSS 16

HVDD 17

H3 18

H4 19

RGVSS 20

RG OUTPUT

DRVSS 5

(LSB) D0 2

4.7F 0.1F

0.1F4.7F

4.7F

0.1F

0.1F4.7F

0.1F

1F

Figure 21. Recommended Circuit Configuration

APPLICATIONS INFORMATION

Circuit Configuration

The AD9948 recommended circuit configuration is shown in

Figure 21. Achieving good image quality from the AD9948

requires careful attention to PCB layout. All signals should be

routed to maintain low noise performance. The CCD output

signal should be directly routed to Pin 27 through a 0.1 µF

capacitor. The master clock CLI should be carefully routed to

Pin 25 to minimize interference with the CCDIN, REFT, and

REFB signals.

The digital outputs and clock inputs are located on Pins 2 to 13

and Pins 31 to 39, and should be connected to the digital ASIC

away from the analog and CCD clock signals. Placing series

resistors close to the digital output pins may help to reduce

digital code transition noise. If the digital outputs must drive a

load larger than 20 pF, buffering is recommended to minimize

additional noise. If the digital ASIC can accept gray code, the

AD9948’s outputs can be selected to output data in gray code

format using the control register Bit D5. Gray coding will

help reduce potential digital transition noise compared with

binary coding.

The H1–H4 and RG traces should have low inductance to

avoid excessive distortion of the signals. Heavier traces are

recommended because of the large transient current demand

on H1–H4 from the capacitive load of the CCD. If possible,

physically locating the AD9948 closer to the CCD will reduce

the inductance on these lines. As always, the routing path

should be as direct as possible from the AD9948 to the CCD.

Grounding and Decoupling Recommendations

As shown in Figure 21, a single ground plane is recommended

for the AD9948. This ground plane should be as continuous as

possible, particularly around Pins 23 to 30. This will ensure that

all analog decoupling capacitors provide the lowest possible

impedance path between the power and bypass pins and their

respective ground pins. All high frequency decoupling capacitors

should be located as close as possible to the package pins. It is

recommended that the exposed paddle on the bottom of the

package be soldered to a large pad, with multiple vias connect-

ing the pad to the ground plane.

All the supply pins must be decoupled to ground with good

quality, high frequency chip capacitors. There should also be a

4.7 µF or larger bypass capacitor for each main supply—AVDD,

RGVDD, HVDD, and DRVDD—although this is not necessary

for each individual pin. In most applications, it is easier to share

the supply for RGVDD and HVDD, which may be done as long

as the individual supply pins are separately bypassed. A separate

3 V supply may be used for DRVDD, but this supply pin should

still be decoupled to the same ground plane as the rest of the

chip. A separate ground for DRVSS is not recommended.

The reference bypass pins (REFT, REFB) should be decoupled

to ground as close as possible to their respective pins. The analog

input (CCDIN) capacitor should also be located close to the pin.

REV. 0

AD9948

–25–

Driving the CLI Input

The AD9948’s master clock input (CLI) may be used in two

different configurations, depending on the application. Figure 23a

shows a typical dc-coupled input from the master clock source.

When the dc-coupled technique is used, the master clock signal

should be at standard 3 V CMOS logic levels. As shown in

Figure 23b, a 1000 pF ac coupling capacitor may be used

between the clock source and the CLI input. In this configura-

tion, the CLI input will self-bias to the proper dc voltage level

of approximately 1.4 V. When the ac-coupled technique is

used, the master clock signal can be as low as ±500 mV in

amplitude.

CCD IMAGER

SIGNAL

OUT

19 14 15 21

H2 RGH3 H4 H1

H1 RG

AD9948

CCDIN

Figure 22a. CCD Connections (2 H-Clock)

CCD IMAGER

SIGNAL

OUT

14 15 21

RGH3 H4

H1 RG

AD9948

CCDIN

H2 H1

18 19

H1 H2

Figure 22b. CCD Connections (4 H-Clock)

CLI

MASTER CLOCK

AD9948

ASIC

Figure 23a. CLI Connection, DC-Coupled

CLI

MASTER CLOCK

AD9948

ASIC

LPF

1nF

Figure 23b. CLI Connection, AC-Coupled

REV. 0–26–

AD9948

HORIZONTAL TIMING SEQUENCE EXAMPLE

Figure 24 shows an example CCD layout. The horizontal regis-

ter contains 28 dummy pixels, which will occur on each line

clocked from the CCD. In the vertical direction, there are 10

optical black (OB) lines at the front of the readout and two at

the back of the readout. The horizontal direction has four OB

pixels in the front and 48 in the back.

To configure the AD9948 horizontal signals for this CCD, three

sequences can be used. Figure 25 shows the first sequence, to be

used during vertical blanking. During this time, there are no

valid OB pixels from the sensor, so the CLPOB signal is not

used. PBLK may be enabled during this time, because no valid

data is available.

Figure 26 shows the recommended sequence for the vertical OB

interval. The clamp signals are used across the whole lines in

order to stabilize the clamp loop of the AD9948.

Figure 27 shows the recommended sequence for the effective

pixel readout. The 48 OB pixels at the end of each line are used

for the CLPOB signal.

USE SEQUENCE 2

USE SEQUENCE 3

SEQUENCE 2 (OPTIONAL)

HORIZONTAL CCD REGISTER

EFFECTIVE IMAGE AREA

28 DUMMY PIXELS

48 OB PIXELS

4 OB PIXELS

10 VERTICAL OB LINES

2 VERTICAL OB LINES

Figure 24. Example CCD Configuration

VERTICAL SHIFT VERT SHIFT

SEQUENCE 1: VERTICAL BLANKING

CCDIN

SHP

SHD

H1/H3

H2/H4

HBLK

PBLK

CLPOB

DUMMY INVALID PIXELSINVALID PIX

Figure 25. Horizontal Sequence during Vertical Blanking

REV. 0

AD9948

–27–

VERTICAL SHIFT VERT SHIFT

SEQUENCE 2: VERTICAL OPTICAL BLACK LINES

CCDIN

SHP

SHD

H1/H3

H2/H4

HBLK

PBLK

CLPOB

OPTICAL BLACK DUMMY OPTICAL BLACK

Figure 26. Horizontal Sequences during Vertical Optical Black Pixels

VERTICAL SHIFT VERT SHIFT

SEQUENCE 3: EFFECTIVE PIXEL LINES

CCDIN

SHP

SHD

H1/H3

H2/H4

HBLK

PBLK

CLPOB

OPTICAL BLACK DUMMY EFFECTIVE PIXELS

OPTICAL BLACK

Figure 27. Horizontal Sequences during Effective Pixels

REV. 0

C03752–0–5/03(0)

–28–

AD9948

OUTLINE DIMENSIONS

40-Lead Lead Frame Chip Scale Package [LFCSP]

6 mm  6 mm Body

(CP-40)

Dimensions shown in millimeters

BOTTOM

VIEW

4.25

3.70 SQ

1.75

TOP

VIEW

6.00

BSC SQ

PIN 1

INDICATOR

5.75

BSC SQ

12 MAX

0.30

0.23

0.18

0.20 REF

SEATING

PLANE

1.00

0.90

0.80

0.05 MAX

0.02 NOM

COPLANARITY

0.08

0.80 MAX

0.65 NOM

4.50

REF

0.50

0.40

0.30

0.50

BSC

PIN 1

INDICATOR

0.60 MAX

COMPLIANT TO JEDEC STANDARDS MO-220-VJJD-2