MURATA-PS ADSQ-1410-EX-C

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ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
PRELIMINARY
PRODUCT OVERVIEW
The ADSQ-1410 is a quad 10MSPS sampling
A/D optimized for applications where low noise
performance and the ability to convert full-scale
step input signals at a 10 MHz conversion rate are
required. With excellent dynamic performance up
to Nyquist frequencies, the ADSQ-1410 is also an
ideal choice for multi-channel, frequency domain
applications.
This functionally complete quad A/D uses a single
rising edge triggered Start Convert signal to control
the conversion cycles of all four A/D’s. The digital
CMOS outputs are multiplexed into pairs providing
two parallel, 3-state output buses. Four indepen-
FEATURES
dent Enable Control pins offer individual output
data and overflow/underflow selection.
A 2.5V precision internal reference, along with individual analog input range selection pins, provides
ideal tracking over temperature while allowing
each channel to be independently configured for an
analog input range of ±1V to ±2.5V.
Available in both surface-mount and through-hole
packages, the ADSQ-1410 requires only ±5V for
internal analog supplies and 2V to 5V supply for logic
outputs. Typical power dissipation is 2.7 Watts.
Common applications include medical imaging,
radar, sonar, communications and instrumentation.
FUNCTIONAL BLOCK DIAGRAM
„
Quad 14-bit resolution; 10 MSPS sampling rate
Individual channel selectable ±1V to ±2.5V input
„
range
Individual channel offset and gain adjustment
„
capabilities
„
Functionally complete; low cost
„
Low noise: 0.5 LSB RMS; no missing codes
„
Excellent dynamic performance: SNR 80db
2V to 5V CMOS logic outputs with overflow/
„
underflow; 3-latency delays
Rising edge-triggered; Individual channel enable
„
/ Hi-z outputs
„
±5V and +2VDD to +5VDD logic output supplies
„
66-pin SMT or TDIP package
20 Overflow_AB
66 B1 (MSB) AB
+5V 4, 10, 25, 30
-5V 5, 11
64 B3 AB
63 B4 AB
Offset Adj A 3
52 EN A
Input A 1
62 B5 AB
61 B6 AB
3-State Register
Sub-Ranging A/D
A
SGND A 2
60 B7 AB
59 B8 AB
Range A 13
58 B9 AB
57 B10 AB
Offset Adj B 31
Sub-Ranging A/D
B
Input B 33
56 B11 AB
3-State Register
55 B12 AB
SGND B 32
54 B13 AB
48 EN B
Range B 17
53 B14 (LSB) AB
51 EN C
Offset Adj C 9
Sub-Ranging A/D
C
Input C 7
21 Overflow_CD
3-State Register
47 B1 (MSB) CD
46 B2 CD
SGND C 8
45 B3 CD
Range C 15
44 B4 CD
„
Developed for image processing applications
„
Ideal for both time and frequency domain
applications
65 B2 AB
+VDD 19, 22
Sub-Ranging A/D
D
Offset Adj D 26
43 B5 CD
3-State Register
42 B6 CD
Input D 28
41 B7 CD
49 EN D
SGND D 27
40 B8 CD
39 B9 CD
Range D 16
38 B10 CD
Timing and Control
+2.5V REF 14
50 START CONV
2.5V REF
37 B11 CD
36 B12 CD
35 B13 CD
AGND 6, 12, 24, 29
OGND 18, 23
34 B14 (LSB) CD
For full details go to
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MDA_ADSQ.B01 Page 1 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
ABSOLUTE MAXIMUM RATINGS
Parameters
Min.
Typ.
Max.
Units
+5VA Supply (Pin 4,10,25,30)
0
–
+5.5
Volts
–5VA Supply (Pin 5,11)
0
–
–5.5
Volts
+VDD (Pins 19,22)
0
–
+7V
Volts
Digital Input (Pin 48,49,50,51,52)
–0.3
–
+VDD +0.5
Volts
Analog Input (Pin 1,7,13,15,16,17,28)
–5
–
+5
Volts
Lead Temperature soldering 10sec
–
–
300
°C
FUNCTIONAL SPECIFICATIONS
(TA = +25°C, VCC = +5V, +VDD = +3.3V, VEE = –5V, 10MSPS sampling rate,
VIN = ±2.5V and a minimum 1 minute warmup unless otherwise specified.)
Analog Input
Min.
Typ.
Max.
Units
Input Voltage Range
±1
–
±2.5
Volts
Input Impedence
–
470
–
Ω
Input Capacitance
–
2
7
pF
+2.4
0.5
2.1
1.6
–
–
+VDD
–
+0.8
Volts
Volts
Volts
Volts
Volts
–
–
–
–
+10
–10
uA
uA
Digital Inputs
Logic Levels
Logic 1 START CONV
Logic 1 ENABLE VDD 2V
Logic 1 ENABLE VDD 3.3V
Logic 1 ENABLE VDD 5.0V
Logic 0
Logic Loading
Logic 1
Logic 0
Performance
Differential Nonlinearity
(fin = 975kHz)
+25°C
0 to 70°C
Extended temperature range
–0.99
–0.99
TBD
±0.5
±0.5
TBD
–
–
–
LSB
LSB
LSB
Integral Nonlinearity
+25°C
0 to 70°C
Extended temperature range
–
–
–
±2.5
±3.0
TBD
–
–
–
LSB
LSB
LSB
Guaranteed No Missing Codes
0 to 70°C
Resolution
Zero Error
+25°C
0 to 70°C
Extended temperature range
Gain Error
+25°C
0 to 70°C
Extended temperature range
14 Bits
–
–
–
–
–
–
0.3
0.3
TBD
0.6
TBD
TBD
–
–
–
–
–
–
%FSR
%FSR
%FSR
%FSR
%FSR
%FSR
Output
Output Coding
Logic Level
Logic 1 (–4mA) +VDD = +3.3V
Logic 0 (4mA) +VDD = +3.3V
Logic Loading 1 +VDD = +3.3V
Logic Loading 0 +VDD = +3.3V
–
–
–
–
–
+0.5
-4
+4
2.495
2.495
–
+2.5
+2.5
–
2.505
2.505
5
Volts
Volts
mA
Dynamic Performance
Min.
Typ.
Max.
Units
–
–
–
-89.5
-88.5
-87.6
–
–
–
db
db
db
–
–
–
-81.3
-81
-78
–
–
–
db
db
db
–
–
–
74.8
74.8
74.6
–
–
–
db
db
db
–
–
–
80.4
80.2
79.6
–
–
–
db
db
db
–
–
–
74.6
74.6
74.4
–
–
–
db
db
db
–
–
–
78.2
78
77
–
–
–
db
db
db
–
–
–
-94.9
-92.1
-91.2
–
–
–
db
db
db
–
–
–
-85.5
-85
-80
–
–
–
db
db
db
Input Bandwidth
Small Signal (–20dB input)
Large Signal (–3dB input)
–
–
33.5
8.5
–
–
MHz
MHz
Aperture Delay Time
–
1
–
ns
Aperture Uncertainty
–
4
–
ps rms
S/H Acquisition Time,
(to ±0.003% FSR)
–
TBD
–
ns
–
-130
–
dB
–
–
121
150
–
–
μVrms
μVrms
–
–
0.99
0.5
–
–
LSB
LSB
Total Harmonic Distortion
(–0.5dB)
RANGE pin voltage = 1V
500kHz
1MHz to
5MHz
RANGE pin voltage = 2.5V
500kHz
1MHz to
5MHz
Signal-to-Noise Ratio
(w/o distortion, –0.5dB)
RANGE pin voltage = 1V
500kHz
1MHz to
5MHz
RANGE pin voltage = 2.5V
500kHz
1MHz to
5MHz
Signal-to-Noise Ratio
(distortion, –0.5dB)
RANGE pin voltage = 1V
500kHz
1MHz to
5MHz
RANGE pin voltage = 2.5V
500kHz
1MHz to
5MHz
Spurious Free Dynamic Range
RANGE pin voltage = 1V
500kHz
1MHz to
5MHz
RANGE pin voltage = 2.5V
500kHz
1MHz to
5MHz
Feedthrough Rejection
Channel under test Fin = 4.85MHz
Other 3 channels Fin = 2.45MHz
Offset Binary
+2.9
–
–
–
Internal Reference
Voltage +25°C
0 to 70°C
External Current
Volts
Volts
mA
mA
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Noise
RANGE pin voltage = 1V
RANGE pin voltage = 2.5V
(grounded input)
RANGE pin voltage = 1V
RANGE pin voltage = 2.5V
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MDA_ADSQ.B01 Page 2 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
FUNCTIONAL SPECIFICATIONS, CONT.
Power Requirements
The fine gain adjustment range is equivalent to the amount of change
induced at the RANGE pin. With the desired Fine Gain Adjustment (as a
percent of full scale) and the maximum voltage expected from the Fine
Gain Adjust circuitry known, and we select a value for R1 that minimizes
the amount of current draw from Vref (typically 1kΩ range), we can then
calculate the value for R3 to be:
Power Supply Ranges
+5VEE Supply
–5VCC Supply
+VDD Supply
+4.75
–5.25
+2V
+5.0
–5.0
+3.3
+5.25
–4.75
+5V
Volts
Volts
Volts
Power Supply Currents
+5V Supply
–5V Supply
+VDD Supply
–
–
–
390
140
12
430
155
20
mA
mA
mA
Power Dissipation
–
2.7
3.1
Watt
Power Supply Rejection
(5%) @25°C
–
–
±0.01
%FSR/%V
Operating Temperature Range
ADSQ-1410
ADSQ-1410EX
0
TBD
–
–
+70
TBD
°C
°C
Eq. 2:
Storage Temperature
–65
–
+125
°C
Where: RANGE is the unadjusted RANGE pin voltage
Environmental
Package Type
Weight
PCB
R3 = R1 Vtrim
Vref %
100
Where: Vtrim = the maximum Fine Gain Adjust voltage
% = the percentage of desired trim range as a % of full scale
Eq. 1:
Defining RANGE as the unadjusted RANGE pin voltage (R3 tied to GND or
Fine Gain Adjust = 0V), we can determine the value of R2 using the following equation:
R2 =
R1 R3 Range
R3 Vref – Range (R1 + R3)
66-Pin, SMT, TDIP
23 grams
FR-4 RoHS TG 170°C UL94-VO
Plastic Shell
Nylon 46, 30% GFR, Stanyl, UL94-VO
Pins
0.020 Sq. Au Plate Phosphor Bronze
For example: Using the circuit shown, a ± 1V output DAC is used to adjust
the gain of a channel with an analog input range of ±2.0V by ± 5%.
Resistor R1 is selected to be 1k Ohm. From Eq. 1: R3 = (1k x 1.0) / (2.0
x 0.05) = 8k Ohm. For an analog input range of ±2.0V the unadjusted
RANGE voltage must be +2.0V. From Eq. 2: R2 = (1k x 8k x 2.0) / (8k x
2.5 - 2.0(1k +8k)) = 8k.
Typical for all channels
TECHNICAL NOTES
The ADSQ-1410 is a designed to function as four-independent sampling
A/D converters each with a selectable analog input range of ±1 to ±2.5
Volts and with independent offset and gain capabilities. Each channel of
the ADSQ-1410 operates from its independent +5V supplies and analog
grounds (AGND & SGND). Channels A&B share a common -5V, +VDD and
OGND_AB (output ground), similarly channels C&D share -5V, +VDD and
OGND_CD. This separation of channels along with strategically placed
ground connections within the ADSQ-1410 provide the excellent channelto-channel isolation performance. For optimal performance PCB layout
and high-speed / high resolution design practices should be observed.
See Layout Considerations.
RANGE & FINE GAIN ADJUSTMENT:
The ADSQ-1410 allows the full-scale range of each individual channel
to be adjusted from 2Vpp to 5Vpp. The ADSQ-1410 provides a precision
+2.5V reference voltage that can be used with a resistor divider network
to set each channel's desired full-scale range. The voltage applied to each
individual RANGE pin will set the full-scale input of that channel to be:
FS = 2 x RANGE pin voltage.
Fine Gain adjustment can be attained with precision changes to the high
impedance RANGE pins using a resistor divider network in conjunction
with a DAC or adjustable voltage source as shown in the Gain Adjust
figure.
Setting the RANGE voltage and providing the proper amount of gain
adjustment can be calculated using the following equations as referred to
the circuitry shown in the Gain Adjust figure.
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R2
Fine Gain
Adjust
R3
Channel A
A/D Range Select
(FS = 2 x VRANGE)
RANGE_A
R1
+2.5V REF
+2.5V REF
ADSQ-1410 Range / Gain Adjust
OFFSET ADJUSTMENT
Offset adjustment is accomplished by applying a ± voltage to the OFFSET
ADJ circuitry as seen in the Input Stage figure. Offset adjustment calculations can be determined using the following equations. It should be noted
that the factory trims that are required in several of the converter’s input
stages will slightly alter the tolerance of the offset adjustment calculations. For Eq. 3 the number of desired codes of adjustment are inserted
to determine the necessary voltage at the OFFSET ADJ pin. For example
with RANGE voltage = 2.5 volts and ±78 codes of adjustment desired corresponds to ±1V at the OFFSET ADJ pin.
Voffset = 2 Range (Codes)
0.0238
Where: RANGE = the RANGE pin voltage
Codes = Desired offset adjustment range
Eq. 3:
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MDA_ADSQ.B01 Page 3 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
For applications that require small full scale input ranges less sensitivity may be required for offset adjustment. In this case an external series
resistor can be added with the internal 20.5kΩ resistor on the OFFSET ADJ
pin. In this case the Offset Voltage can be calculated by:
Eq. 4:
Typical for AB & CD Output Bus
EN_A
Voffset = 2 Range (Codes)
487.9
(Rexternal + 20500)
A/D_ A
Buffer_A
AB Output Bus &
Overflow
Where: RANGE = the RANGE pin voltage
Codes = Desired offset adjustment range
Rexternal = External Offset series resistor
(pins 54-66 & 20)
A/D_ B
Buffer_B
EN_B
20.5k
470
OFFSET ADJ
Output Block Diagram
470
To A/D
Input
Section
VIN ±2.5V
Parameter
SGND
ADSQ-1410 Quad Input Stage
Symbol
Min
Start Conv Period
tc
100
Start Conv Pulse High
tch
45
Start Conv Pulse Low
tcl
45
Output Delay
tod
13
Typ
Max
Unit
1x106
ns
ns
ns
18
27
ns
Table 1. Digital Output And Timing
DIGITAL OUTPUT AND TIMING
The ADSQ-1410 is configured such that the output bits and overflow for
channels A&B are multiplexed on the AB Output Bus (pins 54 - 66 & 20)
and channels C&D are similarly multiplexed on the CD Output Bus (pins
34-47 & 21). See the Output Block Diagram figure. The output drivers are
designed to conveniently operate from VDD = +2V to +5V and are capable
of sinking and sourcing up to 4mA of current. However, switching large
drive currents can cause glitches on the supplies that could couple into
and create disturbances on an ongoing A/D conversion affecting the SINAD
and SNR performance. Applications where high drive current is required
may require additional supply voltage bypassing or external digital buffers.
The EN_ pins are used to select the appropriate output data. EN_ control
pins are active LO (HI= high-z). Caution must be exercised to assure that
both channels on the same bus are not enabled at the same time. Each
data bus of the ADSQ-1410 is capable of providing data throughput at a
20MHz rate. See Enable and Disable timing diagrams and table.
Input logic levels for EN_ pins are dictated by +VDD supply voltage; logic
level for START_CONV is a function of +5V supply. See Functional Specifications: Digital Inputs.
N
N+1
ANALOG
INPUT
tC
t CH
N+2
t CL
START
CONV
t OD
DATA
OUTPUT
Data N-1
Data N
Symbol
Typ
Max
Hi-Z to Active HI
t-pZH
6.6ns
10.6ns
Hi-Z to Active LO
t-pZL
6.6ns
10.6ns
Active HI to Hi-Z
t-pHZ
7.8ns
11.5ns
Active LO to Hi-Z
t-pLZ
7.8ns
11.5ns
Data N-3
Data N-2
(Enable Pin = LO)
ADSQ-1410 Timing Diagram
Parameter
Table 2. Enable and Disable Times
NOTE: Outputs are enabled when ENABLE pins = LO (Hi-Z = HI). Caution must
be taken to assure that shared outputs are not enabled at the same time.
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MDA_ADSQ.B01 Page 4 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
VCC
50% VCC
50% VCC
ENABLE
0V
➀ Output
waveform 1
S1 at VCC
t PZL
t PZL
–VCC
50% VCC
VOL +0.3V
VOL
t PZH
VOH +0.3V
➁ Output
waveform 1
S1 at GND
50% VCC
V OH
–0V
Voltage Waveforms
Enable and Disable Times
Low- and High-Level Enabling
Enable and Disable Times
➀ Waveform 1 is for an output with internal conditions such that the output is active LO and
Hi-Z is pulled 3.3VD through 1k resistor
➁ Waveform 2 is for an output with internal conditions such that the output is active LO and
Hi-Z is pulled GND through 1k resistor
18ns typ
(tod)
START
CONVERT
➀
N-2
N-3
DATA
The START CONV command of the ADSQ-1410 is buffered internally prior
to being distributed to each A/D convert. The multi-stage architecture of
the internal A/D’s uses both the rising and falling edges of each START
CONV pulse in the conversion process and therefore requires START CONV
commands that maintain a minimum of 45ns for both the high and the low
times. At 10MHz clock rate this would require a 50% (±5% )duty cycle.
Due to the analog pipeline architecture of the A/D section a Start Convert
period that exceeds 1ms will allow internal sample and holds to discharge
the held voltages thereby affecting output integrity. Consequently a minimum Start convert rate of 1 kHz is specified.
Clock jitter (aperture jitter) will result in a variation of time interval
between successive A/D conversions which can adversely affect the signal
to noise ratio performance. Low jitter crystal oscillators provide clock
signals at a 50% duty cycle making ideal START CONV sources. Input logic
levels for EN_ pins are dictated by +VDD supply voltage; logic level for
START_CONV is a function of +5V supply. See Functional Specifications:
Digital Inputs.
Layout Considerations
Although the ADSQ-1410 functions in both the analog and digital realms,
in regards to layout it should be treated as an analog component.
Grounding is critical in any high-speed, high resolution data acquisition
system. As such a multilayer PCB is recommended to allow ground planes
as well as isolation of digital and analog signals. Ground planes will significantly reduce impedance and minimize signal return loops. In addition,
the power and ground planes can be arranged so as to provide inherent
distributed capacitance within the PCB.
50ns typ.
N
Start Convert Considerations
N-1
EN A
30ns
The AGND, SGND and OGND grounds should all be connected to a
common ground plane directly beneath the ADSQ-1410. Although using a
common plane beneath the A/D, it may be beneficial to design notches or
“keep-outs” in the ground plane so as to steer ground currents away from
critical signal sensitive areas in the ground plane.
30ns
Each channel of the quad A/D operates from its own supply voltages.
Bypassing from each of these supplies should be done as close to the
respective power and associated ground pins as possible. Bypass ceramic
capacitor values of 1uF and 0.1uF are recommended in most application.
EN B
DATA
A or B OUT
or
(C or D OUT)
DATA-A
N-3
DATA-B
N-3
DATA-A
N-2
DATA-B
N-2
DATA-A
N-1
6.6ns
7.8ns
➀ Assuming single channel OUTPUT ENABLED
Enable Timing Diagram
Overflow
1
0
0
0
0
0
0
0
0
1
Output Coding
MSB
LSB
Input Range
±2.5V
Bipolar Scale
11
11
11
11
10
01
00
00
00
00
+2.499847
+2.499695
+1.875000
+1.250000
±0.000000
–1.250000
–1.875000
–2.499848
–2.500000
–2.500153
+FS – 1/2LSB
+FS – 1LSB
3/4 FS
+1/2 FS
0
–1/2 FS
–3/4 FS
–FS +1LSB
–FS
–FS –1/2LSB
1111
1111
1100
0000
0000
0000
1000
0000
0000
0000
1111
1111
0000
0000
0000
0000
0000
0000
0000
0000
1111
1111
0000
0000
0000
0000
0000
0001
0000
0000
In order to prevent digital switching noise from being coupled into sensitive analog signal paths, the layout designer should assure that digital
signals do not run parallel with signal traces. For ease of layout the ADSQ1410 is designed with all Digital Outputs and START CONVERT one side of
the package and signal pins on the other.
The +2.5V REF pin is used in conjunction with external components to set
the RANGE of each channel. Care should be exercised to assure that the
Reference voltage and its associated divided down voltage applied to the
RANGE pins are bypassed properly and not subject to noise pickup from
digital paths.
Typical Application Connection Diagram
The ADSQ-1410 is a functionally complete quad A/D and as such requires
little externally circuitry for operation. The figure (connection diagram)
shows the typical circuit connections with channels A, B, C operating with
a ±2.5V input range and channel D operating with a gain adjustable input
range less than ±2.5V.
Table 3. Output Coding
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MDA_ADSQ.B01 Page 5 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
+5V
-5V_CD
-5V_AB
+VDD
20 Overflow_AB
66 B1 (MSB) AB
4,10,25,30
11
5
65 B2 AB
19,22
64 B3 AB
1
Input A
2
3
±V
Input A
63 B4 AB
SGND A
62 B5 AB
Offset Adj A
61 B6 AB
60 B7 AB
Input B
±V
33
Input B
59 B8 AB
32
SGND B
58 B9 AB
31
Offset Adj B
57 B10 AB
56 B11 AB
Input C
55 B12 AB
ADSQ-1410
7
Input C
8
SGND C
9
Offset Adj C
54 B13 AB
53 B14 (LSB) AB
±V
Input D
21 Overflow _CD
28
Input D
27
SGND D
26
Offset Adj D
47 B1 (MSB) CD
46 B2 CD
±V
14
+2.5 VREF
13
RANGE A
17
RANGE B
45 B3 CD
44 B4 CD
43 B5 CD
15
42 B6 CD
41 B7 CD
40 B8 CD
RANGE C
RANGE D
Channel D
16
Fine Gain Adjust
AGND
6,12,
OGND
18, 23
ENA
ENB
ENC
END
START
CONV
52
48
51
49
50
24,29
R1
39 B9 CD
38 B10 CD
37 B11 CD
36 B12 CD
±V
R3
35 B13 CD
R2
* Diagram shown with channels A thru C input full scale range equal to ±2.5V
with no gain adjustment. Channel D input range set to < ±2.5V with fine gain
adjustment.
34 B14 (LSB) CD
Connection Diagram
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MDA_ADSQ.B01 Page 6 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
PIN FUNCTIONS
PIN FUNCTIONS, CONT.
Pin Number Name
Description
1, 7, 28, 33
2, 8, 27, 32
3, 9, 26, 31
4, 10, 25, 30
5, 11
6, 12, 24, 29
13
14
15
16
17
18, 23
19, 22
34-47
21
48
49
50
51
52
53-66
20
Signal Input for Respective Channel
Signal Ground for Respective Channel
Offset Adjust for Respective Channel
+5V Analog Supply for Respective Channel
-5V Analog Supply for Respective Channel
Analog Ground for Respective Channel
Channel A Range Adjustment
+2.5V Reference Output Voltage
Channel C Range Adjustment
Channel D Range Adjustment
Channel B Range Adjustment
Digital Ground for Respective Channel
Output Supply for Respective Channel
Data Output Bits for Channels C&D
Overflow/Underflow for Channels C&D
Output Enable Channel B
Output Enable Channel D
Start Convert for all Channels
Output Enable Channel C
Output Enable Channel A
Data Output Bits for Channels A&B
Overflow/Underflow for Channels A&B
INPUT (A, C, D, B)
SGND (A, C, D, B)
OFFSET ADJ (A, C, D, B)
+5V (A, C, D, B)
-5V (A, C, D, B)
AGND (AB, CD)
RANGE_A
+2.5V REF
Range_C
Range D
Range B
OGND_AB
+VDD (AB, CD)
DATA OUT_CD
Overflow_CD
EN_B
EN_D
START CONV
EN_C
EN_A
DATA OUT_AB
Overflow_AB
Table 3. Pin Function Description
INPUT (A, C, D, B) - Pins 1, 7, 28, 33: Analog Input Signal for respective
channels.
SGND (A, C, D, B) - Pins 2, 8, 27, 32: Signal ground for respective channels. SGND connected to AGND and DGND at strategic locations within the
ADSQ-1410.
OFFSET ADJ (A, C, D, B) - Pins 3, 9, 26, 31: Provides independent offset
adjustment for each channel. Designed for ± voltages applied to OFFSET
ADJ pin; leave floating or tied to GND for non-adjustment applications. Applying -1V reduces output by approx. 76 codes; applying +1.0V increases output
by approx. 76 codes with RANGE = 2.5V.
+5V (A, C, D, B) - Pins 4, 10, 25, 30: Individual +5V analog supply pins for
each channel. Bypass to respective AGND pins with 1uF and 0.1uF ceramic
capacitors.
-5V (AB, CD) - Pins 5, 11: Individual -5V analog supply pins for each channel. Bypass to respective AGND pins with 1uF and 0.1uF ceramic capacitors.
AGND (A, C, D, B) - Pins 6, 12, 24, 29: Analog ground (+5V and -5V returns)
for respective channels. AGND connected to SGND and DGND at strategic
locations within the ADSQ-1410.
RANGE (A, B, C, D) - Pin 13, 15, 16, 17: Used with +2.5V REF to select the
respective channel's full scale input range and fine gain adjustment. See
Range and Calibration section.
+2.5V REF - Pin 14: Precision +2.5V output voltage used with RANGE to
select full scale input range for all channels. See Range and Calibration section. Bypass to AGND Plane.
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+VDD (AB, CD) - Pins 19, 22: Supply voltage for digital circuitry. Channels AB share common supply pin, channels CD share common supply pin.
Bypass to respective OGND pins with 1uF and 0.1uF ceramic capacitors.
OGND (AB, CD) - Pins 18, 23: Output ground (OGND_AB and OGND_CD
returns) for associated channels. OGND is connected to AGND and other
OGND at strategic locations within the ADSQ-1410.
DATA_OUT_CD – Pins 34 – 47: Digital data from channels C&D are buffered
internally, with the capability of selecting between active and High-Z states,
and brought out on the DATA_OUT_CD pins. Selection between C or D is controlled by EN_C and EN_D control pins. DATA OUT employs the offset binary
coding format and is powered from +VDD_CD supply.
OVERFLOW_CD - Pin 21: Overflow is a digital output that is multiplexed onto
the output data bus in the same manner as the data bits and is enabled or
inactive (High-Z) along with the corresponding) data outputs (same latency
delay via the respective EN control pin. The signal is LO when the data is
within the valid input range of the corresponding A/D converter and HI when
the input signal is: +FS-1/2LSB <input> -FS-1/2LSB.
EN_C - Pin 51: Control pin for channel C output data. The data output for
channel C is buffered internally with the capability to select between active
and High-Z states. The channel C data output shares pins with channel D
(DATA_OUT_CD). Caution must be exercised to assure that channel C and
channel D are not enabled at the same time. A LO enables the corresponding
channel's output data; a HI places the channel into a High-Z state.
EN_D - Pin 49: Control pin for channel D output data. The data output for
channel D is buffered internally with the capability to select between active
and High-Z states. The channel D data output shares pins with channel C
(DATA_OUT_CD). Caution must be exercised to assure that channel D and
channel C are not enabled at the same time.
DATA_OUT_AB – Pins 53 – 66: Digital data from channels A&B are buffered
internally, with the capability of selecting between active and High-Z states,
and brought out on the DATA_OUT_AB pins. Selection between A or B is
controlled by EN_A and EN_B control pins. DATA OUT employs the offset
binary coding format and is powered from +VDD_AB supply. A LO enables
the corresponding channel's output data; a HI places the channel into a
High-Z state.
OVERFLOW_AB - Pin 20: Overflow is a digital output that is multiplexed onto
the output data bus in the same manner as the data bits and is enabled or
inactive (High-Z) along with the corresponding) data outputs (same latency
delay via the respective EN control pin. The signal is LO when the data is
within the valid input range of the corresponding A/D converter and HI when
the input signal is: +FS-1/2LSB <input> -FS-1/2LSB.
EN_A - Pin 52: Control pin for channel A output data. The data output for
channel A is buffered internally with the capability to select between active
and High-Z states. The channel A data output shares pins with channel B
(DATA_OUT_AB). Caution must be exercised to assure that channel A and
channel B are not enabled at the same time. A LO enables the corresponding
channel's output data; a HI places the channel into a High-Z state.
EN_B - Pin 48: Control pin for channel B output data. The data output for
channel B is buffered internally with the capability to select between active
and High-Z states. The channel B data output shares pins with channel A
(DATA_OUT_AB). Caution must be exercised to assure that channel B and
channel A are not enabled at the same time. A LO enables the corresponding
channel's output data; a HI places the channel into a High-Z state.
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDA_ADSQ.B01 Page 7 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
SPECIFICATION DEFINITIONS
Typical Performance Curves and Plots
Total Harmonic Distortion (THD): Ratio of total RMS harmonic power to
RMS fundamental power
Dynamic DNL
Fs: 4.85 MHz Fs: 10MHz Range Voltage: 2.5V
THD = 10 X log (RMS of all harmonics/RMS of fundamental)
SNR With Distortion (SINAD): Ratio of RMS power present in output,
excluding fundamental: to the RMS fundamental power
SINAD = 10 X log (fundamental RMS / RMS of remaining output);
expressed in db
SNR without Distortion (SNR): Ratio of RMS power present in output,
excluding fundamental and harmonics: to the RMS power of the fundamental
SNR = 10 X log (fundamental RMS / RMS of power present in output,
excluding fundamental and harmonics, to the fundamental; expressed
in db
0.6
0.4
0.2
0
-0.2
-0.4
-0.6
Spurious Free Dynamic Range (SFDR): Difference between fundamental
peak value and the value of highest spike present in the output (harmonic
or spur).
SFRD = Fundamental (dB) – Highest Spur (dB) ; expressed in db
PSSR: Survo-loop is employed applying an input voltage that forces
output codes to FS-1LSB. One supply voltage is changed to the specified
limits and any change in input voltage recorded. The change in input voltage is divided by the full scale voltage and then divided by percent change
in power supplies. The resulting units are % / %.
Zero Error: Survo-loop is employed applying an input voltage that forces
output codes to:
Unipolar devices - LSB on half of the time and all other bits off.
Bipolar devices - MSB on, the LSB on half the time and all other bits off.
Grounded Input Histogram 16384 points
RANGE pin = 2.5V
80%
70%
60%
50%
40%
30%
20%
The input voltage is compared to 0V.
The result is = Input voltage - 0.5 LSB.
10%
0%
Offset Error: Survo-loop is employed applying an input voltage that forces
output codes to LSB on half of the time, and all other bits off.
8193
The input voltage is compared to 0V for unipolar devices, and -0.5 X full
scale for bipolar devices. The result is this difference - 0.5 LSBs.
Full Scale Absolute Accuracy: Survo-loop is employed applying an input
voltage that forces output codes to LSB on half of the time and all other bits
on. The input voltage is compared to full scale for unipolar devices, and 0.5
X full scale for bipolar devices. The result is this difference + 1.5 LSBs.
Gain Error: The result is the difference between the Offset Error result and
the Full Scale Absolute Accuracy result.
Dynamic DNL Min: An AC signal is input to the device. 2n x 128 (2.1e6 for
14 bit converter) samples are taken, and the number of times each code
appears is recorded. The data is normalized using ideal sine wave values.
The result is the most negative and most positive numbers in the array.
8194
More
Grounded Input Histogram 16384 points
RANGE pin = 1V
50.00%
40.00%
30.00%
20.00%
10.00%
Grounded Input RMS Noise: Input to the device is tied to Signal Ground.
2n x 128 (2.1e6 for 14 bit converter) samples are taken and stored in an
array. The result is the RMS value of this array.
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0.00%
8196
8197
8198
8199
8200
8201
8202
8203
More
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDA_ADSQ.B01 Page 8 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
Typical Performance Curves and Plots
FFT 16384 points
Fs: 480 kHz Fs: 10MHz Range pin voltage: 2.5V
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
-140
FFT 16384 points
Fs: 480 kHz Fs: 10MHz Range pin voltage: 1V
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
FFT 16384 points
Fs: 975 kHz Fs: 10MHz Range pin voltage: 2.5V
FFT 16384 points
Fs: 975 kHz Fs: 10MHz Range pin voltage: 1V
0
-10
-20
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
-140
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
FFT 16384 points
Fs: 2.45 MHz Fs: 10MHz Range pin voltage: 2.5V
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
-140
FFT 16384 points
Fs: 2.45 MHz Fs: 10MHz Range pin voltage: 1V
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
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Technical enquiries email: [email protected], tel: +1 508 339 3000
MDA_ADSQ.B01 Page 9 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
Typical Performance Curves and Plots
FFT 16384 points
Fs: 4.85 MHz Fs: 10MHz Range pin voltage: 2.5V
FFT 16384 points
Fs: 4.85 MHz Fs: 10MHz Range pin voltage: 1V
0
-10
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
-140
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
Cross-talk SNR
4.85MHz Input Frequency on Channel under Test
2.42MHz Input Frequency on other 3 Channels
Cross-talk SINAD
4.85MHz Input Frequency on Channel under Test
2.42MHz Input Frequency on other 3 Channels
78.00
81.00
80.50
77.00
80.00
76.00
79.50
75.00
79.00
78.50
74.00
78.00
73.00
77.50
72.00
77.00
71.00
76.50
ADSQ CH_D with
2.42MHz on A,B,C
ADSQ CH_D
Stand Alone
ADSQ CH_C with
2.42MHz on A,B,D
ADSQ CH_C
Stand Alone
ADSQ CH_B with
2.42MHz on A,C,D
Cross-talk Grounded Input Histogram
Test Channel tied to GND – Other 3 Channels with 2.45 MHz FS Input Signal
80%
80%
70%
70%
60%
60%
50%
50%
40%
40%
30%
30%
20%
20%
10%
10%
0%
ADSQ CH_B
Stand Alone
ADSQ CH_A
Stand Alone
ADSQ CH_D with
2.42MHz on A,B,C
ADSQ CH_D
Stand Alone
ADSQ CH_C with
2.42MHz on A,B,D
ADSQ CH_C
Stand Alone
ADSQ CH_B with
2.42MHz on A,C,D
ADSQ CH_B
Stand Alone
ADSQ CH_A with
2.42MHz on B,C,D
ADSQ CH_A
Stand Alone
Cross-talk Grounded Input Histogram
Test channel tied to GND – Other 3 Channels Grounded
ADSQ CH_A with
2.42MHz on B,C,D
70.00
76.00
0%
8193
8194
More
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8193
8194
More
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDA_ADSQ.B01 Page 10 of 11
ADSQ-1410
Quad 14-Bit, 10 MSPS Sampling A/D Converter
INPUT/OUTPUT CONNECTIONS
MECHANICAL SPECIFICATIONS
QUAD INDEPENDENT ADSQ-1410
1.10
[27.94]
PIN
FUNCTION
PIN
FUNCTION
1
INPUT A
66
B1 AB (MSB)
2
SGND A
65
B2 AB
3
OFFSET ADJ A
64
B3 AB
4
+5V A
63
B4 AB
5
–5V A
62
B5 AB
6
AGND A
61
B6 AB
7
INPUT C
60
B7 AB
8
SGND C
59
B8 AB
9
OFFSET ADJ C
58
B9 AB
10
+5V C
57
B10 AB
11
–5V CD
56
B11 AB
12
AGND C
55
B12 AB
13
RANGE A
54
B13 AB
14
+2.5V REF
53
B14 AB (LSB)
15
RANGE C
52
EN A
16
RANGE D
51
EN C
17
RANGE B
50
START CONV
18
OGND_AB
49
EN D
MODEL
19
+VDD_AB
48
EN B
20
OVERFLOW_AB
47
B1 CD (MSB)
ADSQ-1410-C
ADSQ-1410-EX-C
21
OVERFLOW_CD
46
B2 CD
22
+VDD_CD
45
B3 CD
23
OGND_CD
44
B4 CD
24
AGND D
43
B5 CD
25
+5V D
42
B6 CD
26
OFFSET ADJ D
41
B7 CD
27
SGND D
40
B8 CD
28
INPUT D
39
B9 CD
29
AGND B
38
B10 CD
30
+5V B
37
B11 CD
31
OFFSET ADJ B
36
B12 CD
32
SGND B
35
B13 CD
33
INPUT B
34
B14 CD (LSB)
Unless Otherwise Specified
Tolerances:
.xx ±.02
.xxx ±.010
Dimensions in Inches [mm]
Pin 1 Indicator
3.40
[86.36]
0.39 [9.91] Max
0.20 [5.08] Ref
0.100
[2.54]
Typ
0.900
[22.86]
3.200
[81.28]
0.10
[2.54]
Pin 1
33
0.10
[2.54]
66
66X ….020±.002
Gold Plated
Copper Alloy Pin
34
ORDERING INFORMATION
Murata Power Solutions, Inc.
11 Cabot Boulevard, Mansfield, MA 02048-1151 U.S.A.
Tel: (508) 339-3000 (800) 233-2765 Fax: (508) 339-6356
www.murata-ps.com email: [email protected] ISO 9001 and 14001 REGISTERED
05/18/09
Murata Power Solutions, Inc. 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.
© 2009 Murata Power Solutions, Inc.
www.murata-ps.com
OPERATING
TEMPERATURE RANGE
0 to 70°C
PACKAGE
(66-PIN)
SMT Thru-hole
TBD
SMT Thru-hole
USA:
Mansfield (MA), Tel: (508) 339-3000, email: [email protected]
Canada:
Toronto, Tel: (866) 740-1232, email: [email protected]
UK:
Milton Keynes, Tel: +44 (0)1908 615232, email: [email protected]
France:
Montigny Le Bretonneux, Tel: +33 (0)1 34 60 01 01, email: [email protected]
Germany:
München, Tel: +49 (0)89-544334-0, email: [email protected]
Japan:
Tokyo, Tel: 3-3779-1031, email: [email protected]
Osaka, Tel: 6-6354-2025, email: [email protected]
China:
Shanghai, Tel: +86 215 027 3678, email: [email protected]
Guangzhou, Tel: +86 208 221 8066, email: [email protected]
Singapore:
Parkway Centre, Tel: +65 6348 9096, email: [email protected]
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDA_ADSQ.B01 Page 11 of 11