CDS-1401: 14-Bit, Fast-Settling Correlated Double Sampling

®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
PRODUCT OVERVIEW
The CDS-1401 is an application-specific, correlated double sampling (CDS) circuit designed for
electronic-imaging applications that employ CCD’s
(charge coupled devices) as their photodetector. The CDS-1401 has been optimized for use in
digital video applications that employ 10 to 14-bit
A/D converters. The low-noise CDS-1401 can
accurately determine each pixel’s true video signal
level by sequentially sampling the pixel’s offset
signal and its video signal and subtracting the two.
The result is that the consequences of residual
charge, charge injection and low-frequency “kTC”
noise on the CCD’s output floating capacitor are
effectively eliminated. The CDS-1401 can also be
used as a dual sample-hold amplifier in a data
acquisition system.
The CDS-1401 contains two sample-hold
amplifiers and appropriate support/control circuitry.
Features include independent offset-adjust capability for each S/H, adjustment for matching gain
between the two S/H’s, and four control lines for
triggering the A/D converter used in conjunction
with the CDS-1401. The CDS circuit’s “ping-pong”
timing approach (the offset signal of the “n+1”
FEATURES

Use with 10 to 14-bit A/D converters

1.25 Megapixels/second minimum throughput
(14 bits)

±10V input/output ranges, Gain = –1

Low noise, 200μVrms

Two independent S/H amplifiers

Gain matching between S/H's

Offset adjustments for each S/H

Four external A/D control lines

Small package, 24-pin ceramic DDIP

Low power, 700mW

Low cost
pixel can be acquired while the video output of
the “nth” pixel is being converted) guarantees a
minimum throughput, in a 14-bit application, of
1.25MHz. In other words, the true video signal
(minus offset) will be available at the output of the
CDS-1401 every 800ns. This correlates with the
fact that an acquisition time of 400ns is required
for each internal S/H amplifier (10V step setting to
±0.003%). The input and output of the CDS-1401
can swing up to ±10 Volts.
The functionally complete CDS-1401 is packaged in a single, 24-pin, ceramic DDIP. It operates from ±15V and +5V supplies and consumes
700mW. Though the CDS-1401’s approach to
CDS appears straightforward (see Description of
Operation), the circuit actually exploits an elegant
architecture whose tradeoffs enable it to offer
wide-bandwidth, low-noise and highthroughput combinations unachievable until now. The
CDS- 1401 is a generic type of circuit that can be
used with almost any 10 to 14-bit A/D converter.
However, DATEL does offer A/D converters that are
optimized for use with the CDS-1401.
BLOCK DIAGRAM
100k7
1k7
OFFSET ADJUST V1 1
1007
OFFSET ADJUST I1 2
ANALOG INPUT 1
7
S/H1 ROUT
6
S/H1 OUT
CH = 100pF
1k7
–
S/H 1
+
3
OPTIONAL
100k7
OFFSET ADJUST V2
V 9
9007
1k7
ANALOG INPUT 2
8
1k7
OFFSET ADJUST I2 10
CH = 100pF
–
S/H 2
+
4
S/H2
SUMMING NODE
22 V OUT
S/H1 COMMAND 11
18 A/D CLOCK 1
S/H2 COMMAND 12
19 A/D CLOCK 2
17 A/D CLOCK 1
20 A/D CLOCK 2
5, 14, 21, 23
24
13
16
15
ANALOG GROUND
+15V SUPPLY
–15V SUPPLY
+5V DIGITAL
SUPPLY
DIGITAL
GROUND
Figure 1. CDS-1401 Functional Block Diagram
DATEL
•
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 1 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
PARAMETERS
+15V Supply (Pin 24)
–15V Supply (Pin 13)
+5V Supply (Pin 16)
Digital Inputs (Pins 11, 12)
Analog Inputs (Pins 3, 4)
Lead Temp. (10 seconds)
ABSOLUTE MAXIMUM RATINGS
LIMITS
0 to +16
0 to –16
0 to +6
–0.3 to +VDD +0.3
±12
300
UNITS
Volts
Volts
Volts
Volts
Volts
°C
PARAMETERS
Operating Temp. Range, Case
CDS-1401MC
CDS-1401MM
Thermal Impedance
jc
ca
Storage Temperature Range
Package Type
Weight
PHYSICAL/ENVIRONMENTAL
MIN.
TYP.
0
–55
—
—
MAX.
UNITS
+70
+125
°C
°C
—
5
—
°C/Watt
—
22
—
°C/Watt
–65
—
+150
°C
24-pin, metal-sealed ceramic DDIP
0.42 ounces (12 grams)
FUNCTIONAL SPECIFICATIONS
(TA = +25°C, ±Vcc = ±15V, +VDD = +5V, pixel rate = 1.25MHz, and a minimum warmup time of two minutes unless otherwise noted.)
ANALOG INPUTS ➀
Input Voltage Range
Input Resistance
Input Capacitance
DIGITAL INPUT
Logic Levels
Logic "1"
Logic "0"
Logic Loading "1"
Logic Loading "0"
PERFORMANCE
Sample Mode Offset Error - S/H1
Gain Error - S/H1
Pedestal - S/H1
Sample Mode Offset Error - S/H2
Gain Error - S/H2
Pedestal - S/H2
Sample Mode Offset Error - CDS
Differential Gain Error - CDS
Pedestal - CDS
Pixel Rate (14-bit settling) ➁
Input Bandwidth, ±5V
Small Signal (–20dB input)
Large Signal (–0.5dB input)
Slew Rate
Aperture Delay Time
Aperture Uncertainty
S/H Acquisition Time ➁
(to ±0.003%, 10V step)
Hold Mode Settling Time
(to ±0.15mV)
Noise
Feedthrough Rejection
Overvoltage Recovery Time
S/H Saturation Voltage
Droop Rate
ANALOG OUTPUTS ➂
Output Voltage Range
Output Impedance
Output Current
DIGITAL OUTPUTS
Logic Levels
Logic "1"
Logic "0"
Logic Loading "1"
Logic Loading "0"
DATEL
MIN.
±10
—
—
+25°C
TYP.
—
1000
7
MAX.
—
—
15
MIN.
±10
—
—
0 TO +70°C
TYP.
—
1000
7
MAX.
—
—
15
MIN.
±10
—
—
–55 TO +125°C
TYP.
—
1000
7
MAX.
—
—
15
UNITS
Volts
Ohms
pF
+2
—
—
—
—
—
—
—
—
+0.8
+10
–10
+2
—
—
—
—
—
—
—
—
+0.8
+10
–10
+2
—
—
—
—
—
—
—
—
+0.8
+10
–10
Volts
Volts
μA
μA
—
—
—
—
—
—
—
—
—
1.25
±1
±0.2
±15
±1
±0.2
±15
±1
±0.25
±15
—
±10
±1
±35
±10
±1
±35
±10
±1
±35
—
—
—
—
—
—
—
—
—
—
1.25
±2
±0.25
±15
±2
±0.25
±15
±2
±0.3
±15
—
±10
±1
±35
±10
±1
±35
±10
±1
±35
—
—
—
—
—
—
—
—
—
—
1.25
±4
±0.3
±15
±4
±0.3
±15
±4
±0.35
±15
—
±10
±1.5
±35
±10
±1.5
±35
±10
±1.5
±35
—
mV
%
mV
mV
%
mV
mV
%
mV
MHz
—
—
—
—
—
7
5
±80
±10
5
—
—
—
—
—
—
—
—
—
—
7
5
±80
±10
5
—
—
—
—
—
—
—
—
—
—
7
5
±80
±10
5
—
—
—
—
—
MHz
MHz
V/μs
ns
ps rms
—
200
300
—
200
300
—
200
300
ns
—
—
—
—
—
—
100
200
72
400
±12.5
±0.4
—
—
—
—
—
±0.02
—
—
—
—
—
—
100
200
72
400
±12.5
±0.4
—
—
—
—
—
±2
—
—
—
—
—
—
100
200
72
400
±12.5
±0.8
—
—
—
—
—
±4
ns
μVr ms
dB
ns
Volts
mV/μs
±10
—
—
—
0.5
—
—
—
±20
±10
—
—
—
0.5
—
—
—
±20
±10
—
—
—
0.5
—
—
—
±20
Volts
Ohms
mA
+3.9
—
—
—
—
—
—
—
—
+0.4
–4
+4
+3.9
—
—
—
—
—
—
—
—
+0.4
–4
+4
+3.9
—
—
—
—
—
—
—
—
+0.4
–4
+4
Volts
Volts
mA
mA
•
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 2 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
POWER REQUIREMENTS
Power Supply Ranges
+15V Supply
–15V Supply
+5V Supply
Power Supply Currents
+15V Supply
–15V Supply
+5V Supply
Power Dissipation
Power Supply Rejection
MIN.
+25°C
TYP.
MAX.
MIN.
0 TO +70°C
TYP.
MAX.
MIN.
–55 TO +125°C
TYP.
MAX.
UNITS
+14.75
–14.75
+4.75
+15.0
–15.0
+5.0
+15.25
–15.25
+5.25
+14.75
–14.75
+4.75
+15.0
–15.0
+5.0
+15.25
–15.25
+5.25
+14.75
–14.75
+4.75
+15.0
–15.0
+5.0
+15.25
–15.25
+5.25
Volts
Volts
Volts
—
—
—
—
—
+23
–23
+1
700
—
+27
–27
+2
850
88
—
—
—
—
—
+23
–23
+1
700
—
+27
–27
+2
850
88
—
—
—
—
—
+23
–23
+1
700
—
+27
–27
+2
850
88
mA
mA
mA
mW
dB
Footnotes:
➀ Pins 3 and 4.
➁ See Figure 4 for relationship between input voltage, accuracy, and acquisition time.
➂ Pins 6 and 22.
INPUT/OUTPUT CONNECTIONS
PIN FUNCTION
PIN
FUNCTION
1
OFFSET ADJUST V1
24
+15V ANALOG SUPPLY
2
OFFSET ADJUST I1
23
ANALOG GROUND
3
ANALOG INPUT 1
22
V OUT
4
ANALOG INPUT 2
21
ANALOG GROUND
5
ANALOG GROUND
20
A/D CLOCK2
6
S/H1 OUT
19
A/D CLOCK2
7
S/H1 ROUT
18
A/D CLOCK1
8
S/H2 SUMMING NODE
17
A/D CLOCK1
9
OFFSET ADJUST V2
16
+5V DIGITAL SUPPLY
10
OFFSET ADJUST I2
15
DIGITAL GROUND
11
S/H1 COMMAND
14
ANALOG GROUND
12
S/H2 COMMAND
13
–15V ANALOG SUPPLY
TECHNICAL NOTES
1. 1. To achieve specified performance, all power supply pins should be
bypassed with 2.2μF tantalum capacitors in parallel with 0.1μF ceramic capacitors. All ANALOG GROUND (pins 5, 14, 21 and 23) and DIGITAL GROUND
(pin 15) pins should be tied to a large analog ground plane beneath the
package.
2. In the CDS configuration, to avoid saturation of the S/H amplifiers, the
maximum analog inputs and conditions are as follows:
ANALOG INPUT 1 < ±12V
4. To use as a CDS circuit, tie pin 8 (S/H2 SUMMING NODE) to either pin 6
(S/H1 OUT), through a 200 Ohm potentiometer, or directly to pin 7 (S/H1
ROUT). In both cases, the CCD's output is tied to pins 3 (ANALOG INPUT 1)
and 4 (ANALOG INPUT 2). As shown in Figure 5, the 200W potentiometer is
for gain matching.
5. To use as a dual S/H, leave pin 7 (S/H1 ROUT) and pin 8 (S/H2 SUMMING
NODE) floating. Pin 6 (S/H1 OUT) will be the output of S/H1 and pin 22 (V
OUT) will be the output of S/H2.
6. See Figure 4 for acquisition time versus accuracy and input voltage step
amplitude.
(ANALOG INPUT 1 – ANALOG INPUT 2) < ±12V
3. The combined video and reference/offset signal from the CCD array must
be applied to S/H2, while the reference/offset signal is applied to S/H1.
DATEL
•
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 3 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
FUNCTIONAL DESCRIPTION
CORRELATED DOUBLE SAMPLING
All photodetector elements (photodiodes, photomultiplier tubes, focal
plane arrays, charge coupled devices, etc.) have unique output characteristics that call for specific analog-signalprocessing (ASP) functions at their
outputs. Charge coupled devices (CCD’s), in particular, display a number
of unique characteristics. Among them is the fact that the “offset error”
associated with each individual pixel (i.e., the apparent photonic content
of that pixel after having had no light incident upon it) changes each and
every time that particular pixel is accessed.
Most of us think of an offset as a constant parameter that either can
be compensated for (by performing an offset adjustment) or can be
measured, recorded, and subtracted from subsequent readings to yield
more accurate data. Contending with an offset that varies from reading to
reading requires measuring and recording (or capturing and storing) the
offset each and every time, so it can be subtracted from each subsequent
data reading.
The “double sampling” aspect of CDS refers to the operation of sampling
and storing/recording a given pixel’s offset and then sampling the same
pixel’s output an instant later (with both the offset and the video signal
present) and subsequently subtracting the two values to yield what is
referred to as the “valid video” output for that pixel.
The “correlated” in CDS refers to the fact that the two samples must be
taken close together in time because the offset is constantly varying.
Reasons for this phenomena are discussed below.
At the output of all CCD’s, transported pixel charge (electrons) is converted
to a voltage by depositing the charge onto a capacitor (usually called
the output or “floating” capacitor). The voltage that develops across this
capacitor is obviously proportional to the amount of deposited charge
(i.e., the number of electrons) according to ΔV = ΔQ/C. Once settled, the
resulting capacitor voltage is buffered and brought to the CCD’s output pin
as a signal whose amplitude is proportional to the total number of photons
incident upon the relevant pixel.
After the output signal has been recorded, the floating capacitor is
discharged (“reset”, “clamped”, “dumped”) and made ready to accept
charge from the next pixel. This is when the problems begin. (This is a
somewhat oversimplified explanation in that the floating capacitor is not
usually “discharged” but, in fact, “recharged” to some predetermined dc
voltage, usually called the “reference level”. The pixel offset appears as an
output deviation from that reference level.)
The floating capacitor is normally discharged (charged) via a shunt switch
(typically a FET structure) that has a non-zero “on” resistance. When the
switch is on, its effective series resistance exhibits thermal noise (Johnson
noise) due to the random motion of thermally energized charge. Because
the shunt switch is in parallel with the floating capacitor, the instantaneous value of the thermal noise (expressed in either Volts or electrons)
appears across the cap. When the shunt switch is opened, charge/voltage
is left on the floating cap.
The magnitude of this “captured noise voltage” is a function of absolute
temperature (T), the value of the floating capacitor (C) and Boltzman’s
constant (k). It is commonly referred to as “kTC” noise.
The second contributor to the constantly varying pixel offsets is the fact
that, at high pixel rates, the floating capacitor never has time to fully
discharge (charge) during the period in which its shunt switch is closed.
There is always some “residual” charge left on the cap, and the amount of
this charge varies as a function of what was the total charge held during
DATEL
•
the previous pixel. This amount of residual charge is, in fact, deterministic
(if you know the previous charge and the number of time constants in the
discharge period), however, it is less of a contributor than kTC noise.
The third major contributor to pixel offset is the fact that as the shunt FET
is turned off, the voltage across (and the charge stored on) its parasitic
junction capacitances changes. The result is an “injection” of excess
charge onto the floating cap causing a voltage step normally called a
“pedestal.”
The fourth major contributor to pixel offset is a low-frequency noise component (usually called 1/f noise or pink noise) associated with the CCD’s
output buffer amplifier. Due to all of these contributing factors, "pixel
offsets" vary from sample to sample in an inconsistent, unpredictable
manner.
TRADITIONAL APPROACH TO CDS
There are a number of techniques for dealing with the varyingoffset
idiosyncrasy of CCD’s. The most prevalent has been what can be called
the “sample-sample-subtract” technique. This approach requires the use
of two high-speed sample-hold (S/H) amplifiers and a difference amplifier.
The first S/H is used to acquire and hold a given pixel’s offset. Immediately after that, the second S/H acquires and holds the same pixel’s
offset+video signal. After both the S/H outputs have fully settled, the
difference amplifier subtracts the offset from the offset+video yielding the
valid video signal.
CDS-1401 APPROACH (SEE FIGURE 1)
The DATEL CDS-1401 takes a slightly different, though clearly superior,
approach to CDS. It can be called the “samplesubtract- sample” approach.
Note that the CDS-1401 has been configured to offer the greatest amount
of user flexibility. Its two S/H circuits function independently. They have
separate input and output pins. Each has its own independent control
lines. The control-line signals are delayed, buffered, and brought back out
of the package so they can be used to control other circuit functions. Each
S/H has two pins for offset adjusting (if required), one for current and one
for voltage.
In normal operation, the output signal of the CCD is applied simultaneously to the inputs (pins 3 and 4) of both S/H amplifiers. S/H1 will normally
be used to capture and hold each pixel’s offset signal. Therefore, S/H1
is initially in its signal-acquisition mode (logic “1” applied to pin 11, S/
H1 COMMAND). This is also called the sample or track mode. Following a
brief interval during which the output of the CCD and the output of S/H1
are allowed to settle, S/H1 is driven into its hold mode by applying a logic
“0” to pin 11. S/H1 is now holding the pixel’s offset value.
In most straightforward configurations, the output of S/H1 is connected to
the summing node of S/H2 by connecting pin 7 (S/H1 ROUT) to pin 8 (S/H2
SUMMING NODE).
When the offset+video signal appears at the output of the CCD, S/H2
is driven into its signal acquisition mode by applying a logic “1” to pin
12 (S/H2 COMMAND). S/H2 employs a current-summing architecture
that subtracts the output of S/H1 (the offset) from the output of the CCD
(offset+video) while acquiring only the difference signal (i.e., the valid
video). A logic “0” subsequently applied to pin 12 drives S/H2 into its hold
mode, and after a brief transient settling time, the valid video signal appears at pin 22 (V OUT).
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 4 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
RESET N+1
RESET N
OFFSET N
(CCD OUTPUT)
ANALOG INPUT
FOR CDS (Pins 3 and
4 are tied)
100ns typ.
S/H 1 (Pin 11)
OFFSET +
VIDEO N+1
OFFSET N+1
OFFSET +
VIDEO N
HOLD
S/H 2 (Pin 12)
100ns typ.
HOLD
30ns typ.
A/D CLOCK 1 (Pin 17)
A/D CLOCK 1 (Pin 18)
30ns typ.
A/D CLOCK 2 (Pin 19)
A/D CLOCK 2 (Pin 20)
VIDEO SIGNAL N-1
VOLTAGE OUTPUT
VIDEO SIGNAL N
NOTE: Not Drawn to Scale
Figure 2. CDS-1401 Typical Timing Diagram
TIMING NOTES
See Figure 2, Typical Timing Diagram. It is advisable that neither of the
CDS-1401's S/H amplifiers be in their sample/ track mode when large,
high-speed transients (normally associated with clock edges) are occurring
throughout the system. This could result in the S/H amplifiers being driven
into saturation, and they may not recover in time to accurately acquire their
next signal.
For example, S/H1 should not be commanded into the sample mode until
all transients associated with the opening of the shunt switch have begun
to decay. Similarly, S/H2 should not be driven into the sample mode until
all transients associated with the clocking of pixel charge onto the output
capacitor have begun to decay. Therefore, it is generally not a good practice
to use the same clock edge to drive S/H1 into hold (holding the offset) and
S/H2 into sample (to acquire the offset + video signal).
size, the S/H's internal to the CDS-1401 acquire smaller-amplitude signals
quicker than they acquire largeramplitude signals. In "maximum-throughput" applications, assuming "asymmetric" timing can be accommodated,
each S/H should only be given the time it requires, and no more, to acquire
its input signal. Leaving a S/H amp in the sample mode for a longer period
of time has little added benefit.
As an example, the graph shows that it takes 160ns to acquire a 500mV
step to within 10mV of accuracy and 260ns to acquire a 500mV step to
within 0.5mV of accuracy. The figures in this graph are typical values at
room temperature.
The CDS-1401 brings out 4 control lines that can be used to trigger an A/D
converter connected to its output. If the A/D is a sampling type, system timing should be such that the A/D's input S/H amplifier is acquiring the output
of the CDS-1401 at the same time the output is settling to its final value.
S/H's that are in their signal-acquisition modes should be left there as long
as possible (so all signals can settle) and be driven into their hold modes
before any system transients occur. In Figure 2, S/H1 is driven into the
sample mode shortly after the transient from the shunt switch has begun
to decay. S/H1 is then kept in the sample mode while the offset signal and
the S/H output settle. S/H1 is driven into hold just prior to the system clock
pulse(s) that transfers the next pixel charge onto the output capacitor.
For most sampling A/D's, the rising edge of the start-convert pulse drives
the internal S/H into the hold mode under the assumption the S/H has already fully acquired and is tracking the input signal. In this case, the same
edge can not be used to drive S/H2 into the hold mode and simultaneously
initiate the A/D conversion. The output of S/H2 needs time to settle its
sample-to-hold switching transient, and the input S/H of the A/D needs time
to fully acquire its new input signal.
As soon as the transients/noise associated with the charge transport begins
to decay, S/H2 can be driven into the sample mode. S/H2 can then be left in
the sample mode until just before the reset pulse for the output capacitor.
As shown in Figure 1, output line A/D CLOCK1 (pin 18) is a slightly delayed
version of the signal applied to pin 11 (S/H1 COMMAND), and A/D CLOCK1
(pin 17) is its complement. A/D CLOCK2 (pin 19) is a delayed version of the
signal applied to pin 12 (S/H2 COMMAND), and A/D CLOCK2 (pin 20) is its
complement. Any one of these signals, as appropriate, may be used to trigger the A/D conversion.
In Figure 2, S/H's 1 and 2 both have the same acquisition time. If the pixelto-pixel amplitude variation of offset signals is much less than that of video
signals, it may not be necessary for the allocated acquisition time of S/H1
to be as long as that of S/H2.
As shown in the plot (Figure 4) of acquisition times vs. input signal step
DATEL
•
Figure 3 is a typical timing diagram for a CDS-1401 in front of DATEL's 12bit, 1.2MHz sampling A/D, the ADS-CCD1201.
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 5 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
RESET
(CCD OUTPUT)
ANALOG INPUT
FOR CDS
(Pins 3 and 4 are tied)
RESET
OFFSET (N+1)
OFFSET +
VIDEO (N+2)
OFFSET (N+2)
OFFSET +
VIDEO (N+1)
400ns
S/H1
S/H2
400ns
30ns typ.
START CONVERT
90ns typ.
420ns
EOC
OUTPUT
DATA
DATA N-1 VALID
DATA N VALID
DATA N+1 VALID
73ns max.
35ns max.
Figure 3. CDS-1401 in Front of ADS-CCD1201 at fCLK = 1MHz
±0.5mV accuracy
±1mV accuracy
±2mV accuracy
±5mV accuracy
±10mV accuracy
Figure 4. Acquisition Time versus Accuracy and Step Size
DATEL
•
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 6 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
CALIBRATION PROCEDURE
GROSS OFFSET ADJUSTMENT
For gross offset adjustments use pin 2 (OFFSET ADJUST I1) and/or pin 10
(OFFSET ADJUST I2). All connections made to pin 2 and pin 10 should be
very short because these are very sensitive points.
OFFSET ADJUST (FIGURE 5)
Offset and pedestal errors may be compensated for by applying external
voltages to pin 1 (OFFSET ADJUST V1) and/ or pin 9 (OFFSET ADJUST V2)
using either voltage-output DAC’s or potentiometers configured to appear
as voltage sources.
Offset and pedestal errors may also be compensated for by applying external currents to pin 2 (OFFSET ADJUST I1) and/ or pin 10 (OFFSET ADJUST
I2) by using either current-output DAC’s or potentiometers configured to
appear as current sources.
1. Connect pin 8 (S/H2 SUMMING NODE) either directly to pin 7 (S/H1 ROUT)
or through a 200 Ohm potentiometer to pin 6 (S/H1 OUT).
2. Tie pins 3 (ANALOG INPUT 1) and 4 (ANALOG INPUT 2) to pin 5 (ANALOG
GROUND).
3. Adjust OFFSET ADJUST V1 or OFFSET ADJUST I1 (while S/H1 is in the
hold mode) until pin 6 (S/H1 OUT) equals 0V.
Sourcing 1mA into OFFSET ADJUST I1 will cause a –1V offset change at pin
6 (S/H1 OUT). It will also cause a +1V offset change at pin 22 (V OUT) if pin
7 (S/H1 ROUT) is connected to pin 8 (S/H2 SUMMING NODE).
Sourcing 1mA into OFFSET ADJUST I2 will cause a –1V offset change at pin
22 (V OUT).
GAIN MATCHING ADJUSTMENT (DIFFERENTIAL GAIN)
BETWEEN S/H1 AND S/H2
The user can adjust the gain matching (differential gain) between S/H1 and S/
H2 by leaving pin 7 (S/H1 ROUT) floating (open) and connecting a 200 Ohm
potentiometer between pin 6 (S/H1 OUT) and pin 8 (S/H2 SUMMING NODE).
Note, offset adjustment should take place before gain matching adjustment.
Apply a full-scale input to both pins 3 (ANALOG INPUT 1) and 4 (ANALOG
INPUT 2). Adjust the 200 Ohm potentiometer (with both S/H's in the sample
mode) until pin 22 (V OUT) is 0V.
4. Adjust OFFSET ADJUST V2 or OFFSET ADJUST I2 (while S/H2 is in the
hold mode) until pin 22 (VOUT) equals 0V.
If gain matching adjustment is not required, leave pin 6 (S/H1 OUT) floating
(open) and tie pin 7 (S/H1 ROUT) to pin 8 (S/H2 SUMMING NODE).
5. To negate the effect of output droop on the offset-adjust process, each
S/H must be continually switched between its sample and hold modes and
adjusted so its output equals zero immediately after going into the hold
mode.
The sensitivity of the voltage offset adjustments is 100mV per Volt. The
sensitivity of the current offset adjustments is 1V per mA. Pins 1, 2, 9 and
10 should be left open (floating) when not being used for offset adjustment.
+15V
1
OFFSET ADJUST V1
–15V
24
+15V ANALOG SUPPLY
+15V
0.1μF
+
2.2μF
0.1μF
+
2.2μF
CDS-1401
2
3
4
5
OFFSET ADJUST I1
ANALOG INPUT 1
ANALOG INPUT 2
ANALOG GROUND
23
ANALOG GROUND
22
V OUT
21
ANALOG GROUND
20
A/D CLOCK 2
19
A/D CLOCK 2
6
7
2007
8
S/H1 OUT
S/H1 ROUT
S/H2 SUMMING NODE
18
A/D CLOCK 1
17
A/D CLOCK 1
16
+5V DIGITAL SUPPLY
+15V
9
+5V
OFFSET ADJUST V2
15
DIGITAL GROUND
–15V
10
11
12
OFFSET ADJUST I2
14
ANALOG GROUND
S/H1 COMMAND
S/H2 COMMAND
13
–15V ANALOG SUPPLY
–15V
2.2μF
0.1μF
+
Figure 5. CDS-1401 Typical Connection Diagram
DATEL
•
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 7 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
MECHANICAL DIMENSIONS INCHES (mm)
1.31 MAX.
(33.27)
24-PIN DDIP
24
(unless otherwise indicated):
2 place decimal (.XX) ±0.010 (±0.254)
3 place decimal (.XXX) ±0.005 (±0.127)
13
0.80 MAX.
(20.32)
1
Kovar alloy
50 microinches (minimum) gold plating
over 100 microinches (nominal) nickel plating
12
0.100 TYP.
(2.540)
1.100
(27.940)
0.235 MAX.
(5.969)
0.200 MAX.
(5.080)
+0.002
0.010 –0.001
(0.254)
0.190 MAX.
(4.826)
0.100
(2.540)
0.040
(1.016)
0.018 ±0.002
(0.457)
1.31 MAX.
(33.02)
(unless otherwise indicated):
2 place decimal (.XX) ±0.010 (±0.254)
3 place decimal (.XXX) ±0.005 (±0.127)
0.80 MAX.
(20.32)
1
Kovar alloy
50 microinches (minimum) gold plating
over 100 microinches (nominal) nickel plating
12
0.020 TYP.
(0.508)
0.210 MAX.
(5.334)
0.060 TYP.
(1.524)
0.130 TYP.
(3.302)
PIN 1
INDEX
0.100
(2.540)
0.100 TYP.
(2.540)
DATEL
0.100
(2.540)
24-PIN SURFACE MOUNT
13
24
0.600 ±0.010
(15.240)
SEATING
PLANE
0.025
(0.635)
•
0.020
(0.508)
0.015
(0.381)
MAX. radius
for any pin
0.010 TYP.
(0.254)
0.040
(1.016)
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
•
Tel: (508) 339-3000
•
www.datel.com
16 Jan 2013
•
e-mail: [email protected]
MDA_CDS-1401.B03 Page 8 of 9
®
CDS-1401
®
14-Bit, Fast-Settling Correlated Double Sampling Circuit
ORDERING INFORMATION
MODEL NUMBER
OPERATING TEMP. RANGE
PACKAGE TYPE
ROHS
CDS-1401MC
0 to +70°C
TDIP
NO
CDS-1401MM
–55 to +125°C
TDIP
NO
CDS-1401MC-C
0 to +70°C
TDIP
YES
CDS-1401MM-C
–55 to +125°C
TDIP
YES
ACCESSORIES
HS-24
Heat Sink for all
CDS-1401 models
Receptacles for pc board mounting can be ordered through Amp Inc., part number 3-331272-8 (component lead socket), 24 required.
For MIL-STD-883 products, or availability of surface mount packaging, contact DATEL.
DATEL
11 Cabot Boulevard, Mansfield, MA 02048-1151 USA
ITAR and ISO 9001/14001 REGISTERED
. makes no representation that the use of its products in the circuits described herein, or the use of other
technical information contained herein, will not infringe upon existing or future patent rights. The descriptions contained herein do not
imply the granting of licenses to make, use, or sell equipment constructed in accordance therewith. Specifications are subject to change
without notice.
© 2013
www.datel.com • e-mail: [email protected]
16 Jan 2013
MDA_CDS-1401.B03 Page 9 of 9