BB DDC232CGXGT

 DDC232
SBAS331C – AUGUST 2004 – REVISED SEPTEMBER 2006
32-Channel, Current-Input
Analog-to-Digital Converter
FEATURES
•
•
•
•
•
•
•
•
SINGLE-CHIP SOLUTION TO DIRECTLY
MEASURE 32 LOW-LEVEL CURRENTS
HIGH-PRECISION, TRUE INTEGRATING
FUNCTION
INTEGRAL LINEARITY:
±0.025% of Reading ±1.0ppm of FSR
VERY LOW NOISE: 5.3ppm of FSR
LOW POWER: 7mW/channel
ADJUSTABLE FULL-SCALE RANGE
ADJUSTABLE DATA RATE: Up to 6kSPS
– Integration Times Down to 166.5µs
DAISY-CHAINABLE SERIAL INTERFACE
The DDC232 has a serial interface designed for
daisy-chaining in multi-device systems. Simply
connect the output of one device to the input of the
next to create the chain. Common clocking feeds all
the devices in the chain so that the digital overhead
in a multi-DDC232 system is minimal.
The DDC232 uses a +5V analog supply and a +2.7V
to +3.6V digital supply. Operating over the
temperature range of 0°C to +70°C, the DDC232 is
offered in a BGA-64 package.
AVDD
IN1
CT SCANNER DAS
PHOTODIODE SENSORS
X-RAY DETECTION SYSTEMS
Protected by US Patent #5841310
IN2
For each of the 32 inputs, the DDC232 provides a
dual-switched integrator front-end. This configuration
allows for continuous current integration: while one
integrator is being digitized by the onboard A/D
converter, the other is integrating the input current.
Adjustable integration times range from 166µs to 1s,
allowing currents from fAs to µAs to be continuously
measured with outstanding precision.
CLK
CONV
Digital
Filter
Dual
Switched
Integrator
Configuration
and
Control
DIN_CFG
CLK_CFG
RESET
IN3
Dual
Switched
Integrator
∆Σ
Modulator
DESCRIPTION
The DDC232 is a 20-bit, 32-channel, current-input
analog-to-digital (A/D) converter. It combines both
current-to-voltage and A/D conversion so that 32
separate low-level current output devices, such as
photodiodes, can be directly connected to its inputs
and digitized.
DVDD
Dual
Switched
Integrator
∆Σ
Modulator
APPLICATIONS
•
•
•
VREF
IN4
Dual
Switched
Integrator
IN29
Dual
Switched
Integrator
DVALID
DCLK
∆Σ
Modulator
IN30
Dual
Switched
Integrator
IN31
Dual
Switched
Integrator
Digital
Filter
Serial
Interface
DOUT
∆Σ
Modulator
IN32
Digital
Filter
Digital
Filter
DIN
Dual
Switched
Integrator
AGND
DGND
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2004–2006, Texas Instruments Incorporated
DDC232
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SBAS331C – AUGUST 2004 – REVISED SEPTEMBER 2006
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be
more susceptible to damage because very small parametric changes could cause the device not to meet its published
specifications.
PACKAGE/ORDERING INFORMATION
For the most current package and ordering information, see the Package Option Addendum at the end of this
document.
ABSOLUTE MAXIMUM RATINGS (1)
AVDD to AGND
–0.3V to +6V
DVDD to DGND
–0.3V to +3.6V
AGND to DGND
±0.2V
VREF Input to AGND
2.0V to AVDD + 0.3V
Analog Input to AGND
–0.3V to +0.7V
Digital Input Voltage to DGND
–0.3V to DVDD + 0.3V
Digital Output Voltage to DGND
–0.3V to AVDD + 0.3V
Operating Temperature
0°C to +70°C
Storage Temperature
–60°C to +150°C
Junction Temperature (TJ)
(1)
2
+150°C
Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may
degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond
those specified is not implied.
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ELECTRICAL CHARACTERISTICS
At TA = +25°C, AVDD = +5V, DVDD = +3.0V, VREF = +4.096V, tINT = 333µs in Low-Power mode (CLK = 5MHz),
Range = 7, and continuous mode operation, unless otherwise noted.
DDC232C
PARAMETER
TEST CONDITIONS
MIN
TYP
DDC232CK
MAX
MIN
TYP
MAX
UNIT
ANALOG INPUT RANGE
Range 1
45
50
55
45
50
55
pC
Range 2
90
100
110
90
100
110
pC
Range 3
135
150
165
135
150
165
pC
Range 4
180
200
220
180
200
220
pC
Range 5
225
250
275
225
250
275
pC
Range 6
270
300
330
270
300
330
pC
Range 7
315
350
385
315
350
385
pC
Negative Full-Scale Range
–0.4% of Positive Full-Scale Range
–0.4% of Positive Full-Scale Range
pC
Low-Power Mode
3
3
3.125
kSPS
High-Speed Mode
Not Supported
6
6.2
kSPS
320
1,000,000
µs
162
1,000,000
µs
DYNAMIC CHARACTERISTICS
Data Rate
Integration Time, tINT
Continuous Mode, Low-Power Mode
320
Continuous Mode, High-Speed Mode
System Clock (CLK)
3.125
1,000,000
Not Supported
µs
Non-Continuous Mode
50
50
Low-Power Mode, Clk_4x = 0
1
5
1
5
MHz
High-Speed Mode, Clk_4x = 0
1
10
1
10
MHz
Low-Power Mode, Clk_4x = 1
4
20
4
20
MHz
High-Speed Mode, Clk_4x = 1
4
40
4
40
MHz
Data Clock (DCLK)
20
20
MHz
Configuration Clock (CLK_CFG)
20
20
MHz
ACCURACY
Noise, Low-Level Input (1)
CSENSOR (2) = 50pF
5.3
Integral Linearity Error (4)
7
ppm of FSR (3), rms
±0.025% Reading ± 1.0ppm FSR, typ
±0.05% Reading ± 1.5ppm FSR, max
Resolution
Format = 1
20
20
Format = 0
16
16
Bits
Bits
Input Bias Current
±0.1
±10
±0.1
±10
pA
Range Error Match (5)
0.1
0.5
0.1
0.5
% of FSR
±1000
±200
±1000
ppm of FSR
Range Sensitivity to VREF
VREF = 4.096 ±0.1V
1:1
Offset Error
±200
Offset Error Match (5)
±100
DC Bias Voltage (6)
Power-Supply Rejection Ratio
(1)
(2)
(3)
(4)
(5)
(6)
1:1
±100
ppm of FSR
Low-Level Input (< 1% FSR)
±0.1
±2
±0.1
±2
mV
at DC
100
±800
100
±800
ppm of FSR/V
Input is less than 1% of full-scale.
CSENSOR is the capacitance seen at the DDC232 inputs from wiring, photodiode, etc.
FSR is Full-Scale Range.
A best-fit line is used in measuring nonlinearity.
Matching between side A and side B of the same input.
Voltage produced by the DDC232 at its input that is applied to the sensor.
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ELECTRICAL CHARACTERISTICS (continued)
At TA = +25°C, AVDD = +5V, DVDD = +3.0V, VREF = +4.096V, tINT = 333µs in Low-Power mode (CLK = 5MHz),
Range = 7, and continuous mode operation, unless otherwise noted.
DDC232C
PARAMETER
TEST CONDITIONS
MIN
DDC232CK
TYP
MAX
Offset Drift
±0.5
Offset Drift Stability
±0.2
MIN
TYP
MAX
UNIT
5 (7)
±0.5
5 (7)
ppm of FSR/°C
2 (7)
±0.2
2 (7)
ppm of FSR/minute
0.01
1 (7)
0.01
1 (7)
pA/°C
Range Drift (9)
25
50
25
50
ppm/°C
Range Drift Match (10)
±5
PERFORMANCE OVER TEMPERATURE
DC Bias Voltage Drift (8)
Input Bias Current Drift
±3
TA = +25°C to +45°C
µV/°C
±3
±5
ppm/°C
REFERENCE
Voltage
Input Current (11)
4.000
4.096
4.200
4.000
4.096
4.200
V
Average Value with tINT = 333µs
325
325
µA
Average Value with tINT = 166.5µs
650
650
µA
DIGITAL INPUT/OUTPUT
Logic Levels
VIH
(0.8)DVDD
DVDD + 0.1
(0.8)DVDD
DVDD + 0.1
V
VIL
–0.1
(0.2)DVDD
–0.1
(0.2)DVDD
V
VOH
IOH = –500µA
VOL
IOL = 500µA
0.4
0.4
V
0 < VIN < DVDD
±10
±10
µA
Input Current (IIN)
DVDD – 0.4
Data Format (12)
DVDD – 0.4
Straight Binary
V
Straight Binary
POWER-SUPPLY REQUIREMENTS
Analog Power-Supply Voltage (AVDD)
4.75
5.0
5.25
4.75
5.0
5.25
V
Digital Power-Supply Voltage (DVDD)
2.7
3.0
3.6
2.7
3.0
3.6
V
Supply Current
Analog Current
Digital Current
Total Power Dissipation
Per Channel Power Dissipation
(7)
(8)
(9)
(10)
(11)
(12)
4
Low-Power Mode
41
41
mA
High-Speed Mode
Not Supported
60
mA
Low-Power Mode
3.7
3.7
mA
High-Speed Mode
Not Supported
7.0
Low-Power Mode
224
High-Speed Mode
Not Supported
Low-Power Mode
7
High-Speed Mode
Not Supported
288
224
mA
288
mW
9
mW/Channel
320
9
7
mW
10
Ensured by design, not production tested.
Voltage produced by the DDC232 at its input that is applied to the sensor.
Range drift does not include external reference drift.
Matching between side A and side B of the same input.
Input reference current decreases with increasing tINT (see the Voltage Reference section, page 10).
Data format is Straight Binary with a small offset. The number of bits in the output word is controlled by the Format bit.
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SBAS331C – AUGUST 2004 – REVISED SEPTEMBER 2006
PIN CONFIGURATION
Top View
BGA
Columns
H
G
F
E
D
C
B
A
IN21
IN22
IN23
IN24
IN25
IN26
IN27
IN28
1
IN5
IN6
IN7
IN8
IN9
IN10
IN11
IN12
2
IN17
IN18
IN19
IN20
IN29
IN30
IN31
IN32
3
IN1
IN2
IN3
IN4
IN13
IN14
IN15
IN16
QGND
AGND
AGND
AGND
AGND
AGND
AGND
AGND
Rows
4
5
AGND
AVDD
AVDD
AVDD
AGND
DGND
VREF
VREF
6
DVALID
DIN_CFG CLK_CFG
DGND
DGND
RESET
DVDD
DGND
7
DCLK
DGND
CLK
NC
DOUT
DGND
DIN
CONV
8
PIN DESCRIPTIONS
PIN
LOCATION
FUNCTION
DESCRIPTION
IN1–32
Rows 1–4
Analog Input
Analog Inputs for Channels 1 to 32
QGND
H5
Analog
Quiet Analog Ground
AGND
G5, F5, E5, D5, C5, B5, A5, D6, H6
Analog
Analog Ground
DGND
A7, C6, D7, E7, C8, G8
Digital
Digital Ground
AVDD
E6, F6, G6
Analog
Analog Power Supply, +5V Nominal
VREF
A6, B6
Analog Input
External Voltage Reference Input, +4.096V Nominal
DVALID
H7
Digital Output
Data Valid Output, Active Low
DIN_CFG
G7
Digital Input
Configuration Register Data Input
CLK_CFG
F7
Digital Input
Configuration Register Clock Input
RESET
C7
Digital Input
Digital Reset, Active Low
DVDD
B7
Digital
CONV
A8
Digital Input
Conversion Control Input; 0 = Integrate on Side B, 1 = Integrate on Side A
DIN
B8
Digital Input
Serial Data Input
DOUT
D8
Digital Output
NC
E8
No Connect
Do not connect; must be left floating.
CLK
F8
Digital Input
Master Clock Input
DCLK
H8
Digital Input
Serial Data Clock Input
Digital Power Supply, 3.3V Nominal
Serial Data Output
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TYPICAL CHARACTERISTICS
At TA = 25°C, unless otherwise indicated.
NOISE vs CSENSOR
20
Noise (ppm of FSR, rms)
Low−Power Mode
or
High−Speed Mode
18
Noise (ppm of FSR, rms)
NOISE vs CSENSOR
16
CSENSOR Range Range Range Range Range Range Range
(pF)
1
2
3
4
5
6
7
Range 1
14
12
Range 2
10
0
9.3
6.3
5.5
5.2
5.0
4.9
4.8
22
12.4
8.0
6.4
5.8
5.4
5.1
5.0
47
15.0
9.7
7.6
6.5
6.0
5.6
5.3
8
6
4
Range 7
2
0
0
10
20
30
40
50
CSENSOR (pF)
Figure 1.
6
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THEORY OF OPERATION
The block diagram of the DDC232 is shown in
Figure 2. The device contains 32 identical input
channels
that
perform
the
function
of
current-to-voltage integration followed by a
multiplexed A/D conversion. Each input has two
integrators so that the current-to-voltage integration
can be continuous in time. The output of the 64
integrators are switched to 16 delta-sigma (∆Σ)
converters via multiplexers. With the DDC232 in the
continuous integration mode, the output of the
integrators from one side of the inputs will be
AVDD
VREF
digitized while the other 32 integrators are in the
integration mode. This integration and A/D
conversion process is controlled by the system clock,
CLK. The results from side A and side B of each
signal input are stored in a serial output shift register.
The DVALID output goes low when the shift register
contains valid data.
DVDD
CLK
IN1
Dual
Switched
Integrator
CONV
∆Σ
Modulator
IN2
Digital
Filter
Configuration
and
Control
Dual
Switched
Integrator
DIN_CFG
CLK_CFG
RESET
IN3
Dual
Switched
Integrator
∆Σ
Modulator
IN4
Dual
Switched
Integrator
IN29
Dual
Switched
Integrator
DVALID
DCLK
∆Σ
Modulator
IN30
Dual
Switched
Integrator
IN31
Dual
Switched
Integrator
Digital
Filter
Serial
Interface
DOUT
DIN
∆Σ
Modulator
IN32
Digital
Filter
Digital
Filter
Dual
Switched
Integrator
AGND
DGND
Figure 2. DDC232 Block Diagram
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DEVICE OPERATION
Basic Integration Cycle
The topology of the front end of the DDC232 is an
analog integrator as shown in Figure 3. In this
diagram, only input IN1 is shown. The input stage
consists of an operational amplifier, a selectable
feedback capacitor network (CF), and several
switches that implement the integration cycle. The
timing relationships of all of the switches shown in
Figure 3 are illustrated in Figure 4. Figure 4
conceptualizes the operation of the integrator input
stage of the DDC232 and should not be used as an
exact timing tool for design.
See Figure 5 for the block diagrams of the reset,
integrate, wait, and convert states of the integrator
section of the DDC232. This internal switching
network is controlled externally with the convert pin
(CONV), and the system clock (CLK). For the best
noise performance, CONV must be synchronized
with the rising edge of CLK. It is recommended that
CONV toggle within ±10ns of the rising edge of CLK.
The noninverting inputs of the integrators are
connected to ground. Consequently, the DDC232
analog ground should be as clean as possible. The
internal and external capacitors (CF), are shown in
parallel between the inverting input and output of the
operational amplifier. At the beginning of a
conversion, the switches SA/D, SINTA, SINTB, SREF1,
SREF2, and SRESET are set (see Figure 4).
At the completion of an A/D conversion, the charge
on the integration capacitor (CF) is reset with SREF1
and SRESET (see Figure 4 and Figure 5a). This is
done during reset. In this manner, the selected
capacitor is charged to the reference voltage, VREF.
Once the integration capacitor is charged, SREF1 and
SRESET are switched so that VREF is no longer
connected to the amplifier circuit while it waits to
begin integrating (see Figure 5b). With the rising
edge of CONV, SINTA closes, which begins the
integration of side A. This process puts the integrator
stage into its integrate mode (see Figure 5c).
Charge from the input signal is collected on the
integration capacitor, causing the voltage output of
the amplifier to decrease. The falling edge of CONV
stops the integration by switching the input signal
from side A to side B (SINTA and SINTB). Prior to the
falling edge of CONV, the signal on side B was
converted by the A/D converter and reset during the
time that side A was integrating. With the falling edge
of CONV, side B starts integrating the input signal. At
this point, the output voltage of the side A
operational amplifier is presented to the input of the
∆Σ A/D converter (see Figure 5d).
SREF1
VREF
3pF
50pF
Range[2] Bit
25pF
Range[1] Bit
12.5pF
Range[0] Bit
Input
Current
SINTA
SREF2
IN1
SADC1A
SRESET
Photodiode
ESD
Protection
Diodes
SINTB
To Converter
Integrator A
Integrator B (same as A)
Figure 3. Basic Integration Configuration for Input 1
8
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CONV
CLK
SINTA
SINTB
SREF1
SREF2
SRESET
Integrate
Convert
Wait
W a it
Wait
R e se t
Convert
W a it
Configuration of
Integrator A
R e se t
SA/D1A
VREF
Integrator A
Voltage Output
Figure 4. Integration Timing Diagram (see Figure 3)
SREF1
CF
VREF
SINT
SREF2
CF
IN
SREF1
VREF
To Converter
SRESET
SA/D
SINT
SREF2
IN
To Converter
SRESET
SA/D
a) Reset Configuration
CF
SREF1
b) Wait Configuration
VREF
SINT
SREF2
CF
IN
SRESET
SREF1
VREF
To Converter
SA/D
SINT
SREF2
IN
SRESET
c) Integrate Configuration
To Converter
SA/D
d) Convert Configuration
Figure 5. Diagrams for the Four Configurations of the Front-End Integrators
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average VREF current of approximately 325µA. The
amount of charge needed by the ∆Σ converter is
independent of the integration time; therefore,
increasing the integration time lowers the average
current. For example, an integration time of 800µs
lowers the average VREF current to TBDµA.
Integration Capacitors
There are seven different capacitors available
on-chip for both sides of every channel in the
DDC232. These internal capacitors are trimmed in
production to achieve the specified performance for
range error of the DDC232. The range control bits
(Range[2:0]) change the capacitor value for all
integrators. Consequently, all inputs and both sides
of each input will always have the same full-scale
range. Table 1 shows the capacitor value selected
for each range selection.
It is critical that VREF be stable during the different
modes of operation (see Figure 5). The ∆Σ converter
measures the voltage on the integrator with respect
to VREF. Since the integrator capacitors are initially
reset to VREF, any drop in VREF from the time the
capacitors are reset to the time when the converter
measures the integrator output will introduce an
offset. It is also important that VREF be stable over
longer periods of time because changes in VREF
correspond directly to changes in the full-scale
range. Finally, VREF should introduce as little
additional noise as possible.
Table 1. Range Selection
CF
(pF, typ)
INPUT
RANGE
(pC, typ)
–0.04 to 12.5
Range[2]
Range[1]
Range[0]
0
0
0
3
0
0
1
12.5
–0.2 to 50
0
1
0
25
–0.4 to 100
0
1
1
37.5
–0.6 to 150
1
0
0
50
–0.8 to 200
1
0
1
62.5
–0.1 to 250
1
1
0
75
–1.2 to 300
1
1
1
87.5
–1.4 to 350
For these reasons, it is strongly recommended that
the external reference source be buffered with an
operational amplifier, as shown in Figure 6. In this
circuit, the voltage reference is generated by a
+4.096V reference. A low-pass filter to reduce noise
connects the reference to an operational amplifier
configured as a buffer. This amplifier should have
low noise and input/output common-mode ranges
that support VREF. Even though the circuit in
Figure 6 might appear to be unstable due to the
large output capacitors, it works well for most
operational amplifiers. It is not recommended that
series resistance be placed in the output lead to
improve stability since this can cause a drop in
VREF, which produces large offsets.
Voltage Reference
The external voltage reference is used to reset the
integration capacitors before an integration cycle
begins. It is also used by the ∆Σ converter while the
converter is measuring the voltage stored on the
integrators after an integration cycle ends. During
this sampling, the external reference must supply the
charge needed by the ∆Σ converter. For an
integration time of 333µs, this charge translates to an
+5V
+5V
0.10µF
0.47µF
7
2
1
REF3140
6
2
10kΩ
3
+
+
3
To VREF Pin on
the DDC232
OPA350
10µF
0.10µF
10µF
4
Figure 6. Recommended External Voltage Reference Circuit for Best Low-Noise Operation
10
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Frequency Response
CONFIGURATION REGISTER
The frequency response of the DDC232 is set by the
front end integrators and is that of a traditional
continuous time integrator, as shown in Figure 7. By
adjusting tINT, the user can change the 3dB
bandwidth and the location of the notches in the
response. The frequency response of the ∆Σ
converter that follows the front end integrator is of no
consequence because the converter samples a held
signal from the integrators. That is, the input to the
∆Σ converter is always a DC signal. Since the output
of the front end integrators are sampled, aliasing can
occur. Whenever the frequency of the input signal
exceeds one-half of the sampling rate, the signal will
fold back down to lower frequencies.
Some aspects of device operation are controlled by
the onboard configuration register. The DIN_CFG,
CLK_CFG, and RESET pins are used to write to this
register. When beginning a write operation, hold
CONV low and strobe RESET; see Figure 8. Then
begin shifting in the configuration data on DIN_CFG.
Data is written to the configuration register most
significant bit first. The data is internally latched on
the falling edge of CLK_CFG. Partial writes to the
configuration register are not allowed—make sure to
send all 12 bits when updating the register.
0
NOTE: with Format = 1, the test pattern is 304 bits
with only the last 72 bits non-zero. This sequence of
outputs is repeated twice for each DDC232 and
daisy-chaining is supported in configuration
readback. Table 2 shows the test pattern
configuration during readback. Table 3 shows the
timing for the configuration register read and write
operations. Strobe CONV to begin normal operation.
−10
G a in (dB)
Optional readback of the configuration register is
available immediately after the write sequence.
During readback, the 12-bit configuration data
followed by a 4-bit revision id and the test pattern are
shifted out on the DOUT pin on the rising edge of
DCLK.
−20
−30
−40
Table 2. Test Pattern During Readback
−50
0.1
t INT
1
10
t INT
t INT
100
t INT
Frequency
TEST PATTERN
(Hex)
TOTAL
READBACK BITS
0
30F066012480F6h
512
1
30F066012480F69055h
640
Format BIT
Figure 7. TFrequency Response
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tRST
RESET
Configuration Register Operations
tWTRST
Normal Operation
tWTWR
CLK_CFG
t STCF
DIN_CFG
t HDCF
MSB
LSB
Write Configuration Register Data
Read Configuration Register
and Test Pattern
DCLK
DOUT
MSB
LSB
Configuration
Register
Data
Test Pattern
CONV
Figure 8. Configuration Register Write and Read Operations
Table 3. Timing for the Configuration Register Read/Write
12
SYMBOL
DESCRIPTION
MIN
tWTRST
Wait Required from Reset High to First Rising Edge of CLK_CFG
2
µs
tWTWR
Wait Required from Last CLK-CFG of Write Operation to
First CLK_CFG of Read Operation
2
µs
tSTCF
Set-Up Time from DIN_CFG to Falling Edge of CLK_CFG
10
ns
tHDCF
Hold Time for DIN_CFG After Falling Edge of CLK_CFG
10
ns
tRST
Pulse Width for RESET Active
1
µs
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MAX
UNITS
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Configuration Register
Bit 11
Bit 10
Bit 9
Range[2] Range[1] Range[0]
Bits 11–9
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Format
Pwr/Spd
Clk_4x
0
0
0
0
0
Test
Range[2:0] Analog Input Range
000:
001:
010:
011:
Bit 8
Bit 8
12.5pC
50pC
100pC
150pC
100:
101:
110:
111:
200pC
250pC
300pC
350pC (default)
Format
0 = 16-Bit Output
1 = 20-Bit Output (default)
Format selects how many bits are used in the data output word.
Bit 7
(1)
(2)
Pwr/Spd
0 = Low-Power Mode (default)
1 = High-Speed Mode (DDC232CK Only)
Pwr/Spd BIT
MODE
TYPICAL
POWER/CHANNEL (mW)
MAXIMUM CLK
FREQUENCY (MHz) (1)
MAXIMUM
DATA RATE (kHz)
0
Low-Power
7
5
3.125
1 (2)
High-Speed (2)
10
10
6
Assumes Clk_4x = 0.
Only the DDC232CK supports High-Speed mode.
Bit 6
Clk_4x (System Clock Divider)
0 = Internal Clock Divider = 1 (default)
1 = Internal Clock Divider = 4
The Clk_4x input enables an internal divider on the system clock. When Clk_4x = 1, the system
clock is divided by 4. This allows a 4X faster system clock, which in turn provides a finer
quantization of the integration time because the CONV signal needs to be synchronized with the
system clock for the best performance.
Clk_4x BIT
CLK DIVIDER VALUE
CLK FREQUENCY
INTERNAL CLOCK FREQUENCY
0
1
5MHz
5MHz
1
4
20MHz
5MHz
Bits 5–1
00000
Bit 0
Test Mode
0 = Test Mode Off (default)
1 = Test Mode On
When Test Mode is used, the inputs (IN1 through IN32) are disconnected from the DDC232
integrators to enable the user to measure a zero input signal regardless of the current supplied
to the inputs. The test mode works with both the continuous and non-continuous modes.
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DIGITAL INTERFACE
The digital interface of the DDC232 outputs the
digital results via a synchronous serial interface
consisting of a data clock (DCLK), a valid data pin
(DVALID), a serial data output pin (DOUT), and a
serial data input pin (DIN). The integration and
conversion process is fundamentally independent of
the data retrieval process. Consequently, the CLK
and DCLK frequencies need not be the same,
though for best performance, it is highly
recommended that they be derived from the same
clocking source to keep their phase relationship
constant. DIN is only used when multiple converters
are cascaded and should be tied to DGND
otherwise. Depending on tINT, CLK, and DCLK, it is
possible to daisy-chain multiple converters. This
greatly simplifies the interconnection and routing of
the digital outputs in those applications where a large
number of converters are needed. Configuration of
the DDC232 is set by a dedicated register addressed
using the DIN_CFG and CLK_CFG pins.
System and Data Clocks (CLK and CONV)
The system clock is supplied to CLK and the data
clock is supplied to DCLK. Make sure the clock
signals are clean—avoid overshoot or ringing. For
best performance, generate both clocks from the
same clock source. DCLK should be disabled by
taking it low after the data has been shifted out or
while CONV is transitioning.
When using multiple DDC232s, pay close attention
to the DCLK distribution on the printed circuit board
(PCB). In particular, make sure to minimize skew in
the DCLK signal because this can lead to timing
violations in the serial interface specifications. See
the Cascading Multiple Converters section for more
details.
Data Valid (DVALID)
The DVALID signal indicates that data is ready. Data
retrieval may begin after DVALID goes low. This
signal is generated using an internal clock divided
down from the system clock, CLK. The phase
relationship between this internal clock and CLK is
set when power is first applied and is random. Since
the user must synchronize CONV with CLK, the
DVALID signal will have a random phase relationship
14
with CONV. This uncertainty is ± 1/fCLK. Polling
DVALID eliminates any concern about this
relationship. If data read back is timed from CONV,
wait the maximum value of t7 or t8 to insure data is
valid.
Reset (RESET)
The DDC232 is reset asynchronously by taking the
RESET input low, as shown in Figure 9. Make sure
the release pulse is at least 1µs wide. After resetting
the DDC232, wait at least four conversions before
using the data. It is very important that RESET is
glitch-free to avoid unintentional resets.
> 1µs
RESET
Figure 9. Reset Timing
Conversion Rate
The conversion rate of the DDC232 is set by a
combination of the integration time (determined by
the user) and the speed of the A/D conversion
process. The A/D conversion time is primarily a
function of the system clock (CLK) speed. One A/D
conversion cycle encompasses the conversion of two
signals (one side of each dual integrator feeding the
modulator) and the reset time for each of the
integrators involved in the two conversions. In most
situations, the A/D conversion time is shorter than
the integration time. If this condition exists, the
DDC232 will operate in the continuous mode. When
the DDC232 is in the continuous mode, the sensor
output is continuously integrated by one of the two
sides of each input.
In the event that the A/D conversion takes longer
than the integration time, the DDC232 will switch into
a non-continuous mode. In non-continuous mode,
the A/D converter is not able to keep pace with the
speed of the integration process. Consequently, the
integration process is periodically halted until the
digitizing process catches up. These two basic
modes of operation for the DDC232—continuous and
non-continuous modes—are described below.
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Continuous and
Modes
Non-Continuous
Operational
Figure 10 shows the state diagram of the DDC232.
In all, there are eight states. Table 4 provides a brief
explanation of each state.
CONV|mbsy
1
2
CONV • mbsy
Ncont
Ncont
CONV
3
CONV • mbsy
CONV
4
Int A
Cont
5
CONV • mbsy
Int B/Meas A
Cont
CONV • mbsy
CONV
6
CONV
Int A/Meas B
Cont
CONV • mbsy
Int B
Cont
7
Ncont
8
Ncont
CONV • mbsy
CONV|mbsy
State Diagram Notation:
CONV • mbsy = CONV high AND mbsy active.
CONV|mbsy = CONV high OR mbsy active.
Figure 10. Integrate/Measure State Diagram
Four signals are used to control progression around
the state diagram: CONV, mbsy, and their
complements. The state machine uses the level as
opposed to the edges of CONV to control the
progression. mbsy is an internally-generated signal
not available to the user. It is active whenever a
measurement/reset/auto-zero (m/r/az) cycle is in
progress.
During the continuous (cont) mode, mbsy is not
active when CONV toggles. The non-integrating side
is always ready to begin integrating when the other
side finishes its integration. Consequently, monitoring
the current status of CONV is all that is needed to
know the current state. Cont mode operation
corresponds to states 3–6. Two of the states, 3 and
6, only perform an integration (no m/r/az cycle).
mbsy becomes important when operating in the
non-continuous (ncont) mode (states 1, 2, 7, and 8).
Whenever CONV is toggled while mbsy is active, the
DDC232 will enter or remain in either ncont state 1
(or 8). After mbsy goes inactive, state 2 (or 7) is
entered. This state prepares the appropriate side for
integration. In the ncont states, the inputs to the
DDC232 are grounded.
One interesting observation from the state diagram is
that the integrations always alternate between sides
A and B. This relationship holds for any CONV
pattern and is independent of the mode. States 2
and 7 insure this relationship during the ncont mode.
When power is first applied to the DDC232, the
beginning state is either 1 or 8, depending on the
initial level of CONV. For CONV held high at
power-up, the beginning state is 1. Conversely, for
CONV held low at power-up, the beginning state is 8.
In general, there is a symmetry in the state diagram
between states 1–8, 2–7, 3–6, and 4–5. Inverting
CONV results in the states progressing through their
symmetrical match.
Table 4. State Descriptions
STATE
MODE
DESCRIPTION
1
Ncont
Complete m/r/az of side A, then side B (if previous state is state 4). Initial power-up state
when CONV is initially held High.
2
Ncont
Prepare side A for integration.
3
Cont
Integrate on side A.
4
Cont
Integrate on side B; m/r/az on side A.
5
Cont
Integrate on side A; m/r/az on side B.
6
Cont
Integrate on side B.
7
Ncont
Prepare side B for integration.
8
Ncont
Complete m/r/az of side B, then side A (if previous state is state 5). Initial power-up state
when CONV is initially held Low.
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TIMING EXAMPLES
diagram. The following two traces show when
integrations and measurement cycles are underway.
The internal signal mbsy is shown next. Finally,
DVALID is given. As described in the data sheet,
DVALID goes active low when data is ready to be
retrieved from the DDC232. It stays low until DCLK is
taken high and then back low by the user. The text
below the DVALID pulse indicates the side of the
data available to be read and arrows help match the
data to the corresponding integration.
Continuous Mode
A few timing diagrams help illustrate the operation of
the integrate/measure state machine. These
diagrams are shown in Figure 11 through Figure 16.
Table 5 gives generalized timing specifications in
units of CLK periods for Clk_4x = 0. If Clk_4x = 1,
these values increase by a factor of 4 because of the
internal clock divider. Values (in µs) for Table 5 can
be easily found for a given CLK.
Figure 11 shows a few integration cycles beginning
with initial power-up for a cont mode example. The
top signal is CONV and is supplied by the user. The
next line indicates the current state in the state
CONV
State
8
Integration
Status
7
6
5
4
5
Integrate B
Integrate A
Integrate B
Integrate A
m/r/az
Status
m/r/az B
m/r/az A
m/r/az B
tMRAZ
mbsy
DVALID
tCMDR
t=0
Power−Up
Side B
Data
Side A
Data
Side B
Data
Figure 11. Continuous Mode Timing
Table 5. Timing Specifications Generalized in CLK Periods
VALUE
(CLK periods with Clk_4x = 0)
SYMBOL
16
Low-Power Mode
High-Speed Mode
tMRAZ
DESCRIPTION
Cont mode m/r/az cycle
1552 ± 2
1612 ± 2
tCMDR
Cont mode data ready
1382 ± 2
1382 ± 2
tNCDR1
1st ncont mode data ready
TBD
TBD
tNCDR2
2nd ncont mode data ready
TBD
TBD
tNCMRAZ
Ncont mode m/r/az cycle
TBD
TBD
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In Figure 11, the first state is ncont state 8. The
DDC232 always powers up in the ncont mode. In this
case, the first state is 8 because CONV is initially
low. After the first two states, cont mode operation is
reached and the states begin toggling between 4 and
5. From now on, the input is being continuously
integrated, either on side A or side B. The time
needed for the m/r/az cycle, tMRAZ, is the same time
that determines the boundary between the cont and
ncont modes described earlier in the Overview
section. DVALID goes low after CONV toggles in
time tCMDR, indicating that data is ready to be
retrieved.
See Figure 12 for the timing diagram of the internal
operations occurring during continuous mode
operation. Table 6 gives the timing specifications of
the internal operations occurring during continuous
mode operation.
End Integration Side B
Start Integration Side A
End Integration Side A
Start Integration Side B
tINT
CONV
t INT
Side B
Side A
A/D Conversion
Odd Channels (Internal)
End Integration Side A
Start Integration Side B
Side A
tADCONV
tADRST
Side A
A/D Conversion
Even Channels (Internal)
Side B
tADCONV
tIRST
tADRST
t IRST
DVALID
Side B
Data Ready
Side A
Data Ready
Figure 12. Timing Diagram for DDC232 Internal Operation in Continuous Mode
Table 6. Timing for the Internal Operation in Continuous Mode
Low-Power Mode
(CLK = 5MHz)
SYMBOL
tINT
tADCONV
tADRST
tIRST
DESCRIPTION
MIN
Integration Period (continuous mode)
320
A/D Conversion Time (internally controlled)
TYP
High-Speed Mode
(CLK = 9.6MHz)
MAX
MIN
1,000,000
162
TYP
MAX
UNITS
1,000,000
µs
135.6
TBD
µs
A/D Conversion Reset Time (internally controlled)
3.2
TBD
µs
Integrator Reset Time (internally controlled)
36
TBD
µs
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Non-Continuous Mode
Figure 13 and Figure 14 illustrate operation in non-continuous mode.
Start Integration Side A
End Integration Side A
Start Integration Side B
Start Integration Side A
End Integration Side B
Wait State
Release
State
tINT
CONV
tINT
A/D Conversion
Odd Channels
tNCRL
tADCONV
A/D Conversion
Even Channels
tADCONV
tADRST
tNCIRST
DVALID
Side A Data Ready
Side B Data Ready
tNCDR2
t NCDR1
Figure 13. Conversion Detail for the Internal Operation of Non-Continuous Mode
with Side A Integrated First
Table 7. DDC232 Internal Timing in Non-Continuous Mode
CLK = 5MHz, Clk_4x = 0
SYMBOL
tINT
tADCONV
DESCRIPTION
MIN
Integration Time (non-continuous mode)
TBD
TYP
A/D Conversion Time (internally controlled)
tADRST
A/D Conversion Reset Time (internally controlled)
tNCIRST
Non-Continuous Mode Integrator Reset Time (internally controlled)
MAX
UNITS
1,000,000
µs
135.6
µs
3.2
µs
TBD
µs
tNCRL
Release Time
tNCDR1
1st Non-Continuous Mode Data Ready
TBD
TBD
µs
tNCDR2
2nd Non-Continuous Mode Data Ready
TBD
Start Integration Side B
Start Integration Side B
End Integration Side B
Start Integration Side A
Release
State
End Integration Side A
CONV
Wait State
tINT
tINT
A/D Conversion
Odd Channels
tNCRL
tADCONV
A/D Conversion
Even Channels
t ADCONV
t ADRST
tNCIRST
DVALID
Side B
Data Ready
Side A
Data Ready
Figure 14. Internal Operation Timing Diagram Non-Continuous Mode with Side B Integrated First
18
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is increased so that tINT is always ≥ tMRAZ as shown
in Figure 16 (see Figure 13 and Table 7, page 18).
With a longer tINT, the m/r/az cycle has enough time
to finish before the next integration begins and
continuous integration of the input signal is possible.
For the special case of the very first integration when
changing to the cont mode, tINT can be < tMRAZ. This
is allowed because there is no simultaneous m/r/az
cycle on the side B during state 3—therefore, there
is no need to wait for it to finish before ending the
integration on side A.
Changing Between Modes
Changing from cont to ncont mode occurs whenever
tINT < tMRAZ. Figure 15 shows an example of this
transition. In this figure, cont mode is entered when
the integration on side A is completed before the
m/r/az cycle on side B is complete. The DDC232
completes the measurement on sides B and A during
states 8 and 7 with the input signal shorted to
ground. Ncont integration begins with state 6.
Changing from ncont to cont mode occurs when tINT
CONV
State
5
4
5
8
Continuous
Integration
Status
m/r/az
Status
Integrate A
Integrate B
m/r/az B
m/r/az A
7
6
5
Int B
Int A
Non−Continuous
Int A
m/r/az B
m/r/az A
m/r/az B
mbsy
Figure 15. Changing from Continuous Mode to Non-Continuous Mode
CONV
State
3
4
1
2
Non−Continuous
Integration
Status
m/r/az
Status
Int A
Int B
m/r/az A
3
4
Continuous
Integrate A
m/r/az B
Integrate B
m/r/az A
mbsy
Figure 16. Changing from Non-Continuous Mode to Continuous Mode
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DATA FORMAT
Table 8. Ideal Output Code (1) vs Input Signal
The serial output data is provided in an offset binary
code as shown in Table 8. The Format bit in the
configuration register selects how many bits are used
in the output word. When Format = 1, 20 bits are
used. When Format = 0, the lower 4 bits are
truncated so that only 16 bits are used. Note that the
LSB size is 16 times bigger when Format = 0. An
offset is included in the output to allow slightly
negative inputs (for example, from board leakages)
from clipping the reading. This offset is
approximately 0.4% of the positive full-scale.
INPUT
SIGNAL
IDEAL OUTPUT CODE
FORMAT = 1
IDEAL OUTPUT CODE
FORMAT = 0
≥ 100% FS
1111 1111 1111 1111 1111
1111 1111 1111 1111
0.001531% FS
0000 0001 0000 0001 0000
0000 0001 0000 0001
0.001436% FS
0000 0001 0000 0000 1111
0000 0001 0000 0000
0.000191% FS
0000 0001 0000 0000 0010
0000 0001 0000 0000
0.000096% FS
0000 0001 0000 0000 0001
0000 0001 0000 0000
0% FS
0000 0001 0000 0000 0000
0000 0001 0000 0000
–0.3955% FS
0000 0000 0000 0000 0000
0000 0000 0000 0000
(1)
DATA RETRIEVAL
Excludes the effects of noise, INL, offset, and gain errors.
Setting the Format bit = 0 (16-bit output word) will
reduce the time needed to retrieve data by 20%
since there are fewer bits to shift out. This can be
useful in multichannel systems requiring only 16 bits
of resolution.
In both the continuous and non-continuous modes of
operation, the data from the last conversion is
available for retrieval on the falling edge of DVALID
(see Figure 17 and Table 9). Data is shifted out on
the falling edge of the data clock, DCLK.
Make sure not to retrieve data around changes in
CONV because this can introduce noise. Stop
activity on DCLK at least 10µs before or after a
CONV transition.
CLK
tPDCDV
DVALID
tPDDCDV
tHDDODV
DCLK
t HDDODC
Input 32
MSB
DOUT
Input
32
LSB
tPDDCDO
Input
31
MSB
Input 5
LSB
Input 4
MSB
Input 2
LSB
Input 1
MSB
Input 1
LSB
Input 32
MSB
Figure 17. Digital Interface Timing Diagram for Data Retrieval From a Single DDC232
Table 9. Timing for DDC232 Data Retrieval
SYMBOL
20
MIN
Propagation Delay from Falling Edge of CLK to DVALID Low
10
5
tPDDCDV
Propagation Delay from Falling Edge of DCLK to DVALID High
tHDDODV
Hold Time that DOUT is Valid Before the Falling Edge of DVALID
tHDDODC
Hold Time that DOUT is Valid After Falling Edge of DCLK
tPDDCDO
(1)
DESCRIPTION
tPDCDV
(1)
Propagation Delay from Falling Edge of DCLK to Valid DOUT
With a maximum load of one DDC232 (4pF typical) with an additional load of 5pF.
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MAX
UNITS
ns
ns
400
ns
4
ns
25
ns
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Figure 19 shows the timing diagram when the DIN
input is used to daisy-chain several devices.
Table 10 gives the timing specification for data
retrieval using DIN.
Cascading Multiple Converters
Multiple DDC232 units can be connected in serial
configuration; see Figure 18.
DOUT can be used with DIN to daisy-chain multiple
DDC232 devices together to minimize wiring. In this
mode of operation, the serial data output is shifted
through multiple DDC232s; see Figure 18.
DVALID
DCLK
IN4
IN3
IN2
IN1
3
2
1
IN30
IN29
30
29
DIN
4
IN32
IN31
DDC232
32
DOUT
31
IN2
IN1
34
IN3
35
33
IN4
IN30
IN29
62
61
DIN
36
IN32
IN31
DDC232
64
DOUT
63
IN2
IN1
IN3
67
66
IN4
68
65
IN30
IN29
94
DIN
DCLK
DVALID
DCLK
DVALID
DDC232
93
IN2
IN1
98
97
IN32
IN3
99
IN31
IN4
100
DOUT
96
IN30
IN29
126
DIN
95
DDC232
125
IN32
IN31
128
Sensor
DOUT
127
Data
Retrieval
Output
DCLK
DVALID
Data Clock
Figure 18. Daisy-Chained DDC232s
CLK
DVALID
DCLK
t STDIDC
tHDDIDC
DIN
DOUT
Input
128
MSB
Input
128
LSB
Input
127
MSB
Input 3
LSB
Input 2
MSB
Input 2
LSB
Input 1
MSB
Input 1
LSB
Input
128
MSB
Figure 19. Timing Diagram When Using DDC232 DIN Function; See Figure 18
Table 10. Timing for DDC232 Data Retrieval Using DIN
SYMBOL
DESCRIPTION
MIN
TYP
MAX
UNITS
tSTDIDC
Set-Up Time from DIN to Falling Edge of DCLK
10
ns
tHDDIDC
Hold Time for DIN After Falling Edge of DCLK
10
ns
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RETRIEVAL BEFORE CONV TOGGLES
(CONTINUOUS MODE)
Data retrieval before CONV toggles is the most
straightforward method. Data retrieval begins soon
after DVALID goes low and finishes before CONV
toggles, as shown in Figure 20. For best
performance, data retrieval must stop tSDCV before
CONV toggles. This method is most appropriate for
longer integration times. The maximum time
available for readback is tINT – tCMDR – tSDCV. For
DCLK = 10MHz and CLK = 5MHz, the maximum
number of DDC232s that can be daisy-chained
together (FORMAT = 1) is calculated by Equation 1:
CONV
DVALID
t INT * ǒt CMDR ) t SDCVǓ
(20 32)t DCLK
NOTE: (16 × 32)τDCLK is used for FORMAT = 0,
where tDCLK is the period of the data clock. For
example, if tINT = 1000µs and DCLK = 10MHz, the
maximum number of DDC232s with FORMAT = 1 is
shown in Equation 2:
1000ms * 286.8ms
+ 11.14 ³ 11 DDC232
(640)(100ns)
(2)
(or 13 for FORMAT = 0)
tINT
tINT
t CMDR
(1)
tSDCV
DCLK
…
…
DOUT
…
…
Side B
Data
Side A
Data
Figure 20. Readback Before CONV Toggles
Table 11. Timing for Readback
CLK = 5MHz, Clk_4x = 0
SYMBOL
tSDCV
22
DESCRIPTION
MIN
Data Retrieval Shutdown Before or After Edge of CONV
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TYP
MAX
UNITS
µs
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RETRIEVAL AFTER CONV TOGGLES
(CONTINUOUS MODE)
(20
For shorter integration times, more time is available if
data retrieval begins after CONV toggles and ends
before the new data is ready. Data retrieval must
wait tSDCV after CONV toggles before beginning. See
Figure 21 for an example of this. The maximum time
available for retrieval is tCMDR – (tSDCV + tHDDODV),
regardless of tINT. The maximum number of
DDC232s that can be daisy-chained together with
FORMAT = 1 is calculated by Equation 3:
CONV
266ms
32)t DCLK
(3)
NOTE: (16 × 32)τDCLK is for FORMAT = 0.
For DCLK = 10MHz, the maximum number of
DDC232s is 4 (or 5 for FORMAT = 0).
tINT
tINT
tINT
DVALID
tCMDR
tSDCV
DCLK
…
DOUT
tHDDODV
…
…
…
…
…
Side A
Data
Side B
Data
Side A
Data
Figure 21. Readback After CONV Toggles
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23
DDC232
www.ti.com
SBAS331C – AUGUST 2004 – REVISED SEPTEMBER 2006
t INT * ǒt SDCV ) t SDCV ) t HDDODVǓ
(20 32)t DCLK
RETRIEVAL BEFORE AND AFTER CONV
TOGGLES (CONTINUOUS MODE)
For the absolute maximum time for data retrieval,
data can be retrieved before and after CONV
toggles. Nearly all of tINT is available for data
retrieval. Figure 22 illustrates how this is done by
combining the two previous methods. Pause the
retrieval during CONV toggling to prevent digital
noise, as discussed previously, and finish before the
next data is ready. The maximum number of
DDC232s that can be daisy-chained together with
FORMAT = 1 is:
CONV
tINT
NOTE: (16 × 32)τDCLK is used for FORMAT = 0.
For tINT = 400µs and DCLK = 10MHz, the maximum
number
of
DDC232s
is
5
(or
7
for
FORMAT = 0).
tINT
tINT
t SDCV
DVALID
tHDDODV
t SDCV
DCLK
…
…
…
…
…
…
DOUT
…
…
…
…
…
…
Side B
Data
Side A
Data
Figure 22. Readback Before and After CONV Toggles
24
(4)
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DDC232
www.ti.com
SBAS331C – AUGUST 2004 – REVISED SEPTEMBER 2006
RETRIEVAL: NON-CONTINUOUS MODE
The time available is tNCDR2 – (tINT – tNCDR1). Data
from the second integration must be retrieved before
the next round of integration begins. This time is
highly dependent on the pattern used to generate
CONV. As with the continuous mode, data retrieval
must halt before and after CONV toggles (tSDCV) and
be completed before new data is ready (tHDDODV).
Retrieving in non-continuous mode is slightly
different as compared with the continuous mode. As
illustrated in Figure 23, DVALID goes low in time
tNCDR1 after the first integration completes. If tINT is
shorter than this time, all of tNCDR2 is available to
retrieve data before the other side data is ready. For
tINT > tNCDR1, the first integration data is ready before
the second integration completes. Data retrieval
must be delayed until the second integration
completes, leaving less time available for retrieval.
t IN T
CO NV
t IN T
t IN T
t IN T
D VALID
tNCDR 1
tN C D R 2
DC LK
…
…
DO UT
…
…
Side A
Side B
Data
Data
Figure 23. Readback in Non-Continuous Mode
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25
DDC232
www.ti.com
SBAS331C – AUGUST 2004 – REVISED SEPTEMBER 2006
POWER-UP SEQUENCING
LAYOUT
Prior to power-up, all digital and analog inputs must
be low. At the time of power-up, all of these signals
should remain low until the power supplies have
stabilized, as shown in Figure 24. At this time, begin
supplying the master clock signal to the CLK pin.
Wait for time tPOR, then give a RESET pulse. After
releasing RESET, the configuration register must be
programmed. Table 12 shows the timing for the
power-up sequence.
POWER SUPPLIES AND GROUNDING
Both AVDD and DVDD should be as quiet as
possible. It is particularly important to eliminate noise
from AVDD that is non-synchronous with the
DDC232 operation. Figure 25 illustrates how to
supply power to the DDC232. Each supply of the
DDC232 should be bypassed with 10µF solid
tantalum capacitors. It is recommended that both the
analog and digital grounds (AGND and DGND) be
connected to a single ground plane on the printed
circuit board (PCB).
tPOR
VA
Power Supplies
t RST
AVDD
AGND
10µF
RESET
DDC232
VD
DVDD
DGND
10µF
Figure 24. DDC232 Timing Diagram at Power-Up
Table 12. Timing for DDC232 Power-Up Sequence
SYMBOL
26
TYP
MAX
UNITS
Figure 25. Power-Supply Connections
DESCRIPTION
MIN
tPOR
Wait After Power-Up
Until Reset
250
ms
Shielding Analog Signal Paths
tRST
Reset Low Width
1
µs
As with any precision circuit, careful PCB layout will
ensure the best performance. It is essential to make
short, direct interconnections and avoid stray wiring
capacitance—particularly at the analog input pins
and QGND. These analog input pins are
high-impedance and extremely sensitive to
extraneous noise. The QGND pin should be treated
as a sensitive analog signal and connected directly
to the supply ground with proper shielding. Leakage
currents between the PCB traces can exceed the
input bias current of the DDC232 if shielding is not
implemented. Digital signals should be kept as far as
possible from the analog input signals on the PCB.
Submit Documentation Feedback
PACKAGE OPTION ADDENDUM
www.ti.com
3-Oct-2006
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
DDC232CGXGR
ACTIVE
BGA
GXG
64
1000
TBD
SN/PB
Level-3-240C-168 HR
DDC232CGXGT
ACTIVE
BGA
GXG
64
250
TBD
SN/PB
Level-3-240C-168 HR
Lead/Ball Finish
MSL Peak Temp (3)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
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Addendum-Page 1
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