MAXIM MAX1003

19-1236; Rev 0; 6/97
KIT
ATION
EVALU
E
L
B
AVAILA
Low-Power, 90Msps, Dual 6-Bit ADC
____________________________Features
♦ Two Matched 6-Bit ADCs
♦ High Sampling Rate: 90Msps per ADC
♦ Low Power Dissipation: 350mW
♦ Excellent Dynamic Performance:
5.85 ENOB with 20MHz Analog Input
5.7 ENOB with 50MHz Analog Input
♦ ±1/4LSB INL and DNL (typ)
♦ Internal Bandgap Voltage Reference
♦ Internal Oscillator with Overdrive Capability
♦ 55MHz (-0.5dB) Bandwidth Input Amplifiers with
True Differential Inputs
♦ User-Selectable Input Full-Scale Range
(125mVp-p, 250mVp-p, or 500mVp-p)
♦ 1/4LSB Channel-to-Channel Offset Matching (typ)
♦ 0.1dB Gain and 0.5° Phase Matching (typ)
♦ Single-Ended or Differential Input Drive
♦ Flexible, 3.3V, CMOS-Compatible Digital Outputs
________________________Applications
Direct Broadcast Satellite (DBS) Receivers
VSAT Receivers
______________Ordering Information
Wide Local Area Networks (WLANs)
Cable Television Set-Top Boxes
MAX1003CAX
PART
TEMP. RANGE
PIN-PACKAGE
0°C to +70°C
36 SSOP
Pin Configuration appears at end of data sheet.
_________________________________________________________Functional Diagram
IOCC+
IOCC-
IIN+
IIN-
INPUT
AMP
I
ADC
I
VREF
6
OFFSET
CORRECTION I
GAIN
QIN-
CLOCK
OUT
MAX1003
VREF
ADC
Q
QOCC+
DCLK
TNK-
OFFSET
CORRECTION Q
INPUT
AMP
Q
DI0–DI5
TNK+
CLOCK
DRIVER
BANDGAP
REFERENCE
QIN+
6
DATA
BUFFER
I
6
DATA
BUFFER
Q
6
DQ0–DQ5
QOCC-
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800
MAX1003
_______________General Description
The MAX1003 is a dual, 6-bit analog-to-digital converter
(ADC) that combines high-speed, low-power operation
with a user-selectable input range, an internal reference, and a clock oscillator. The dual parallel ADCs are
designed to convert in-phase (I) and quadrature (Q)
analog signals into two 6-bit, offset-binary-coded digital
outputs at sampling rates up to 90Msps. The ability to
directly interface with baseband I and Q signals makes
the MAX1003 ideal for use in direct-broadcast satellite,
VSAT, and QAM16 demodulation applications.
The MAX1003 input amplifiers feature true differential
inputs, a -0.5dB analog bandwidth of 55MHz, and userprogrammable input full-scale ranges of 125mVp-p,
250mVp-p, or 500mVp-p. With an AC-coupled input
signal, matching performance between input channels
is typically better than 0.1dB gain, 1/4LSB offset, and
0.5° phase. Dynamic performance is 5.85 effective
number of bits (ENOB) with a 20MHz analog input signal, or 5.7 ENOB with a 50MHz signal.
The MAX1003 operates with +5V analog and +3.3V digital supplies for easy interfacing to +3.3V-logic-compatible digital signal processors and microprocessors. It
comes in a 36-pin SSOP package.
MAX1003
Low-Power, 90Msps, Dual 6-Bit ADC
ABSOLUTE MAXIMUM RATINGS
VCC to GND ............................................................-0.3V to 6.5V
VCCO to OGND ........................................................-0.3V to 6.5V
GND to OGND ........................................................-0.3V to 0.3V
Digital and Clock Output Pins to OGND...-0.3V to VCCO (10sec)
All Other Pins to GND...............................................-0.3V to VCC
Continuous Power Dissipation (TA = +70°C)
SSOP (derate 11.8mW/°C above +70°C) ...................941mW
Operating Temperature Range...............................0°C to +70°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, <10sec)...........................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
DC ELECTRICAL CHARACTERISTICS
(VCC = +5V ±5%, VCCO = 3.3V ±300mV, TA = TMIN to TMAX, unless otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
DC ACCURACY (Note 1)
Resolution
RES
6
Integral Nonlinearity
INL
-0.5
±0.25
0.5
LSB
Bits
Differential Nonlinearity
DNL
No missing codes over temperature
-0.5
±0.25
0.5
LSB
VFSH
GAIN = VCC (high gain)
118.75
125
131.25
Full-Scale Input Range
VFSM
GAIN = open (mid gain)
237.5
250
262.5
VFSL
GAIN = GND (low gain)
475
500
525
mVp-p
INVERTING AND NONINVERTING ANALOG INPUTS
Input Open-Circuit Voltage
VAOC
2.25
2.35
2.45
V
Input Resistance
RIN
13
20
29
kΩ
Input Capacitance
CIN
Guaranteed by design
3
5
pF
Common-Mode Voltage Range
VCM
Other analog input driven with external source
(Note 2)
1.75
2.75
V
ROSC
Other oscillator input tied to VCC + 0.3V
4.8
12.1
kΩ
OSCILLATOR INPUTS
Oscillator Input Resistance
8
DIGITAL OUTPUTS (DI0–DI5, DQ0–DQ5)
Digital Outputs Logic-High
Voltage
VOH
ISOURCE = 50µA
Digital Outputs Logic-Low
Voltage
VOL
ISINK = 400µA
0.7VCCO
V
0.5
V
63
104
mA
-75
-40
dB
21
mA
POWER SUPPLY
Supply Current
Power-Supply Rejection Ratio
Digital Outputs Supply Current
Power Dissipation
2
ICC
PSRR
VCC = 4.75V to 5.25V (Note 3)
ICCO
20MHz, full-scale I and Q analog inputs,
CL = 15pF (Note 4)
PD
350
_______________________________________________________________________________________
mW
Low-Power, 90Msps, Dual 6-Bit ADC
(VCC = +5V ±5%, VCCO = 3.3V ±300mV, TA = +25°C, unless otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
DYNAMIC PERFORMANCE (Gain = open, external 90MHz clock (Figure 7), VINI = VINQ = 20MHz sine, amplitude -1dB below
full scale, unless otherwise noted.)
Maximum Sample Rate
fMAX
Analog Input -0.5dB Bandwidth
BW
90
GAIN = GND, open, VCC
GAIN = open (mid gain)
5.7
ENOBH
ENOBL
GAIN = VCC (high gain)
GAIN = GND (low gain)
5.8
5.85
SINAD
GAIN = open (mid gain)
35.5
I channel
-0.5
0.5
Q channel
-0.5
0.5
OFF
Crosstalk Between ADCs
XTLK
Offset Mismatch Between ADCs
OMM
Phase Match Between ADCs
MHz
5.85
GAIN = open (mid gain), fIN = 50MHz,
-1dB below full scale
Input Offset (Note 5)
Amplitude Match Between
ADCs
5.6
ENOBM
Effective Number of Bits
Signal-to-Noise plus Distortion
Ratio
Msps
55
Bits
37
dB
-55
(Note 5)
LSB
dB
-0.5
±0.25
0.5
LSB
AM
-0.2
±0.1
0.2
dB
PM
-2
±0.5
2
degrees
TIMING CHARACTERISTICS (Data outputs: RL = 1MΩ, CL = 15pF)
Clock to Data Propagation
Delay
tPD
(Note 6)
3.6
ns
Data Valid Skew
tSKEW
(Note 6)
1.5
ns
Input to DCLK Delay
tDCLK
TNK+ to DCLK (Note 6)
5.3
ns
Aperture Delay
tAD
Figure 8
7.5
ns
Pipeline Delay
PD
Figure 8
1
clock
cycle
Note 1: Best-fit straight-line linearity method.
Note 2: A typical application will AC couple the analog input to the DC bias level present at the analog inputs (typically 2.35V).
However, it is also possible to DC couple the analog input (using differential or single-ended drive) within this commonmode input range (Figures 4 and 5).
Note 3: PSRR is defined as the change in the mid-gain full-scale range as a function of the variation in VCC supply voltage,
expressed in decibels.
Note 4: The current in the VCCO supply is a strong function of the capacitive loading on the digital outputs. To minimize supply transients and achieve optimal dynamic performance, reduce the capacitive-loading effects by keeping line lengths on the digital outputs to a minimum.
Note 5: Offset-correction compensation enabled, 0.22µF at Q and I compensation inputs (Figures 2 and 3).
Note 6: tPD and tSKEW are measured from the 1.4V level of the output clock, to the 1.4V level of either the rising or falling edge of a
data bit. tDCLK is measured from the 50% level of the clock-overdrive signal on TNK+ to the 1.4V level of DCLK. The capacitive load on the outputs is 15pF.
_______________________________________________________________________________________
3
MAX1003
AC ELECTRICAL CHARACTERISTICS
__________________________________________Typical Operating Characteristics
(VCC = +5V ±5%, VCCO = 3.3V ±300mV, fCLK = 90Msps, GAIN = open (midgain) MAX1003 evaluation kit, TA = +25°C, unless
otherwise noted.)
EFFECTIVE NUMBER OF BITS
vs. ANALOG INPUT FREQUENCY
EFFECTIVE NUMBER OF BITS
vs. SAMPLING/CLOCK FREQUENCY
ANALOG INPUT BANDWIDTH
EFFECTIVE NUMBER OF BITS
MAGNITUDE (dB)
-0.2
5.4
5.2
-0.4
-0.6
MAX1003-03
0
5.8
5.6
6.0
MAX1003-02
MAX1003-01
6.0
5.9
5.8
5.7
-0.8
5.6
-1.0
5.5
fCLK = 90Msps
fIN = 20MHz
5.0
100
10
1
ANALOG INPUT FREQUENCY (MHz)
10
1
100
OSCILLATOR OPEN-LOOP PHASE NOISE
vs. FREQUENCY OFFSET
100
FFT PLOT
0
MAX1003-04
-50
fIN = 19.9512MHz
fCLK = 90.000MHz
1024 POINTS
AC COUPLED
SINGLE ENDED
AVERAGED
AMPLITUDE (dB)
-70
PHASE NOISE (dBc)
10
CLOCK FREQUENCY (MHz)
ANALOG INPUT FREQUENCY (MHz)
-90
-110
MAX1003-05
EFFECTIVE NUMBER OF BITS
-20
-40
-130
-60
10k
1k
100k
1M
0
18
27
36
FREQUENCY (MHz)
INTEGRAL NONLINEARITY
vs. CODE
DIFFERENTIAL NONLINEARITY
vs. CODE
45
MAX1003-07
MAX1003-06
0.50
0.25
DNL (LSB)
0.25
0
0
-0.25
-0.25
-0.50
-0.50
0
10
20
30
CODE
4
9
FREQUENCY OFFSET FROM CARRIER (Hz)
0.50
INL (LSB)
MAX1003
Low-Power, 90Msps, Dual 6-Bit ADC
40
50
60 64
0
10
20
30
40
CODE
_______________________________________________________________________________________
50
60 64
Low-Power, 90Msps, Dual 6-Bit ADC
PIN
NAME
1
GAIN
FUNCTION
2
IOCC+
Positive I-Channel Offset-Correction Compensation. Connect a 0.22µF capacitor for AC-coupled
inputs. Ground for DC-coupled inputs.
3
IOCC-
Negative I-Channel Offset-Correction Compensation. Connect a 0.22µF capacitor for AC-coupled
inputs. Ground for DC-coupled inputs.
4
IIN+
I-Channel Noninverting Analog Input
5
IIN-
I-Channel Inverting Analog Input
6
VCC
+5V ±5% Supply. Bypass with a 0.01µF capacitor to GND (pin 7).
7, 11, 12,
18, 19
GND
Analog Ground
8
VCC
+5V ±5% Supply. Bypass with a 0.01µF capacitor to GND (pin 11).
9
TNK+
Positive Oscillator/Clock Input
10
TNK-
Negative Oscillator/Clock Input
13
VCC
+5V ±5% Supply. Bypass with a 0.01µF capacitor to GND (pin 12).
14
QIN-
Q-Channel Inverting Analog Input
15
QIN+
Q-Channel Noninverting Analog Input
16
QOCC-
Negative Q-Channel Offset-Correction Compensation. Connect a 0.22µF capacitor for AC-coupled
inputs. Ground for DC-coupled inputs.
17
QOCC+
Positive Q-Channel Offset-Correction Compensation. Connect a 0.22µF capacitor for AC-coupled
inputs. Ground for DC-coupled inputs.
Gain-Select Input. Sets input full-scale range: 125/250/500mVp-p (Table 1).
20–25
DQ5–DQ0
26, 28
VCCO
Q-Channel Digital Outputs 0–5. DQ5 is the most significant bit (MSB).
Digital Output Supply, +3.3V ±300mV. Bypass each with a 47pF capacitor to OGND (pin 27).
27
OGND
Digital Output Ground
Digital Clock Output. Frames the output data.
29
DCLK
30–35
DI0–DI5
I-Channel Digital Outputs 0–5. DI5 is the most significant bit (MSB).
36
VCC
+5V ±5% Supply. Bypass with a 0.01µF capacitor to GND (pin 19).
_______________Detailed Description
Converter Operation
The MAX1003 contains two 6-bit analog-to-digital converters (ADCs), a buffered voltage reference, and oscillator circuitry. The ADCs use a flash conversion
technique to convert an analog input signal into a 6-bit
parallel digital output code. The MAX1003’s unique
design includes 63 fully differential comparators and a
proprietary encoding scheme that ensures no more
than 1LSB dynamic encoding error. The control logic
interfaces easily to most digital signal processors
(DSPs) and microprocessors (µPs) with +3.3V CMOScompatible logic interfaces. Figure 1 shows the
MAX1003 in a typical application.
Programmable Input Amplifiers
The MAX1003 has two (I and Q) programmable-gain
input amplifiers with a -0.5dB bandwidth of 55MHz and
true differential inputs. To maximize performance in
high-speed systems, each amplifier has less than 5pF
of input capacitance. The input amplifier gain is programmed, via the GAIN pin, to provide three possible
input full-scale ranges (FSRs) as shown in Table 1.
Table 1. Input Amplifier Programming
GAIN
INPUT FULL-SCALE RANGE
(mVp-p)
GND
500
Open
250
VCC
125
_______________________________________________________________________________________
5
MAX1003
______________________________________________________________Pin Description
MAX1003
Low-Power, 90Msps, Dual 6-Bit ADC
Single-ended and differential AC-coupled input circuits
are shown in Figures 2 and 3. Each of the amplifier
inputs is internally biased to a 2.35V reference through
a 20kΩ resistor, eliminating external DC bias circuits. A
series 0.1µF capacitor is required at each amplifier
input for AC-coupled signals.
When operating with AC-coupled inputs, the input
amplifiers’ DC offset voltage is nulled to within ±1/2LSB
by an on-chip offset-correction amplifier. An external
compensation capacitor is required to set the dominant
pole of the offset-correction amplifier’s frequency
response (Figures 2 and 3). The compensation capacitor will determine the low-frequency corner of the analog input response according to the following formula:
fc = 1 / (0.1 x C)
where C is the value of the compensation capacitor in
µF, and fc is the corner frequency in Hz.
LNB
75Ω CABLE
950MHz TO 2150MHz
F-CONNECTOR
INPUT
KU BAND
OR
VARACTOR-TUNED
PRESELECTION FILTER
FROM TANK VOLTAGE
VCC
AGC
AGC
RFIN
6 BITS
IOUT
RFIN
0
90Msps
90
IIN
CLK IN
MAX2102
DSP
6 BITS
EXTERNAL
VCO
DATA
BUFFER
QOUT
DATA
BUFFER
QIN
LO
DIV
ADC CLOCK
LO
MAX1003
TANK
SYNTHESIZER
MODCTL
OR
MOD GND
TANK
TSA5055
or EQUIV.
Figure 1. Commercial Satellite Receiver System
6
_______________________________________________________________________________________
FIN
CAR
Low-Power, 90Msps, Dual 6-Bit ADC
_OCC+
_OCC+
_OCC-
0.1µF
_IN+
INPUT
AMP
VSOURCE
_IN+
INPUT
AMP
VSOURCE
_IN-
_IN-
0.1µF
0.1µF
20k
MAX1003
20k
20k
2.35V INTERNAL REFERENCE
Figure 3. Differential AC-Coupled Input
Figure 2. Single-Ended AC-Coupled Input
OFFSET CORRECTION DISABLED
_OCC+
MAX1003
20k
2.35V INTERNAL REFERENCE
OFFSET CORRECTION DISABLED
_OCC-
_OCC+
OFFSET
CORRECTION
_IN+
INPUT
AMP
VSOURCE
INPUT
AMP
VSOURCE
_IN-
VREF
1.75V TO 2.75V
_OCCOFFSET
CORRECTION
_IN+
20k
_OCCOFFSET
CORRECTION
OFFSET
CORRECTION
0.1µF
MAX1003
0.22µF
0.22µF
_IN-
MAX1003
20k
2.35V INTERNAL REFERENCE
Figure 4. Single-Ended DC-Coupled Input
For applications where a DC component of the input
signal is present, Figures 4 and 5 show single-ended
and differential DC-coupled input circuits. The amplifiers’ input common-mode voltage range extends from
1.75V to 2.75V. To prevent attenuation of the input
signal’s DC component in this mode, disable the offsetcorrection amplifier by grounding the _OCC+ and
_OCC- pins for the I and Q blocks (Figures 4 and 5).
20k
DIFFERENTIAL SOURCE
WITH COMMON MODE
FROM 1.75V TO 2.75V.
MAX1003
20k
2.35V INTERNAL REFERENCE
Figure 5. Differential DC-Coupled Input
ADCs
The I and Q ADC blocks receive the analog signals
from the respective I and Q input amplifiers. The ADCs
use flash conversion with 63 fully differential comparators to digitize the analog input signal into a 6-bit output
in offset binary format.
_______________________________________________________________________________________
7
MAX1003
Low-Power, 90Msps, Dual 6-Bit ADC
The MAX1003 features a proprietary encoding scheme
that ensures no more than 1LSB dynamic encoding
error. Dynamic encoding errors resulting from
metastable states may occur when the analog input
voltage, at the time the sample is taken, falls close to
the decision point for any one of the input comparators.
The resulting output code for typical converters can be
incorrect, including false full- or zero-scale outputs. The
MAX1003’s unique design reduces the magnitude of
this type of error to 1LSB.
Internal Voltage Reference
An internal buffered bandgap reference is included on
the MAX1003 to drive the ADCs’ reference ladders. The
on-chip reference and buffer eliminate any external
(high-impedance) connections to the reference ladder,
minimizing the potential for noise coupling from external circuitry while ensuring that the voltage reference,
input amplifier, and reference ladder track well with
variations of temperature and power supplies.
Oscillator Circuit
The MAX1003 includes a differential oscillator, which is
controlled by an external parallel resonant (tank) network as shown in Figure 6. Alternatively, the oscillator
may be overdriven with an external clock source as
shown in Figure 7.
Internal Clock Operation (Tank)
If the tank circuit is used, the resonant inductor should
have a sufficiently high Q and a self-resonant frequency (SRF) of at least twice the intended oscillator frequency. Coilcraft’s 1008HS-221, with an SRF of
700MHz and a Q of 45, works well for this application.
Generate different clock frequency ranges by adjusting
varactor and tank elements.
An internal clock-driver buffer is included to provide
sharp clock edges to the internal flash comparators.
The buffer ensures that the comparators are simultaneously clocked, maximizing the ADCs’ effective number
of bits (ENOB) performance.
47k
VCLK = 300mVp-p TO 1.25Vp-p
47pF
TNK+
10k
5pF
VTUNE
TNK+
VCLK
TNK-
47pF
Z0 = 50Ω
CLK
DRIVER
220nH
0.1µF
50Ω
MAX1003
47k
50Ω
CLK
DRIVER
TNK0.1µF
MAX1003
50Ω
VTUNE = 0V TO 8V
fOSC = 70MHz TO 110MHz
VARACTOR DIODE PAIR IS M/A-COM MA4ST079CK-287 (SOT23 PACKAGE)
INDUCTOR COILCRAFT 1008HS-221.
Figure 6. Tank Resonator Oscillator
8
Figure 7. External Clock Drive Circuit
_______________________________________________________________________________________
Low-Power, 90Msps, Dual 6-Bit ADC
MAX1003
N
N+1
ANALOG
INPUT
N+2
tAD
50%
TNK+
(INPUT CLOCK)
tDCLK
1.4V
tPD
DCLK
tSKEW
DATA OUT
DATA VALID N - 1
1.4V
DATA VALID N
Figure 8. MAX1003 Timing Diagram
Output Data Format
The conversion results are output on a dual, 6-bit-wide
data bus. Data is latched into the ADC output latch following a pipeline delay of one clock cycle, as shown in
Figure 8. Output data is clocked out of the respective
ADC’s data output pins (D_0 through D_5) on the rising
edge of the clock output (DCLK), with a DCLK-to-data
propagation delay (tPD) of 3.6ns. The MAX1003 outputs
are +3.3V CMOS-logic compatible.
Transfer Function
Figure 9 shows the MAX1003’s nominal transfer function.
Output coding is offset binary with 1LSB = FSR / 63.
111111
111110
111101
OUTPUT CODE
External Clock Operation
To accommodate designs that use an external clock,
the MAX1003’s internal oscillator can be overdriven by
an external clock source as shown in Figure 7. The
external clock source should be a sinusoid to minimize
clock phase noise and jitter, which can degrade the
ADCs’ ENOB performance. AC couple the clock source
(recommended voltage level is approximately 1Vp-p) to
the oscillator inputs as shown in Figure 7.
100001
100000
011111
011110
000011
000010
000001
000000
-FSR
2
0
1LSB
INPUT VOLTAGE (_IN+ TO _IN-)
FSR
2
Figure 9. Ideal Transfer Function
_______________________________________________________________________________________
9
MAX1003
Low-Power, 90Msps, Dual 6-Bit ADC
__________Applications Information
_____________Dynamic Performance
The MAX1003 is designed with separate analog and
digital power-supply and ground connections to isolate
high-current digital noise spikes from the more sensitive analog circuitry. The high-current digital output
ground (OGND) and analog ground (GND) should be
at the same DC level, connected at only one location
on the board. This will provide best noise immunity and
improved conversion accuracy. Use of separate
ground planes is strongly recommended.
Signal-to-noise and distortion (SINAD) is the ratio of the
fundamental input frequency’s RMS amplitude to all
other ADC output signals. The output spectrum is limited to frequencies above DC and below one-half the
ADC sample rate.
The theoretical minimum analog-to-digital noise is
caused by quantization error, and results directly from
the ADC’s resolution: SNR = (6.02N + 1.76)dB, where
N is the number of bits of resolution. Therefore, a perfect 6-bit ADC can do no better than 38dB.
The FFT Plot (see Typical Operating Characteristics)
shows the result of sampling a pure 20MHz sinusoid at
a 90MHz clock rate. This FFT plot of the output shows
the output level in various spectral bands. The plot has
been averaged to reduce the quantization noise floor
and reveal the low-amplitude spurs. This emphasizes
the excellent spurious-free dynamic range of the
MAX1003.
The effective resolution (or effective number of bits) the
ADC provides can be measured by transposing the
equation that converts resolution to SINAD: N =
(SINAD - 1.76) / 6.02 (see Typical Operating
Characteristics).
The entire board needs good DC bypassing for both
analog and digital supplies. Place the power-supply
bypass capacitors close to where the power is routed
onto the board, i.e., close to the connector. 10µF electrolytic capacitors with low-ESR ratings are recommended. For best effective bits performance, minimize
capacitive loading at the digital outputs. Keep the digital output traces as short as possible.
The MAX1003 requires a +5V ±5% power supply for
the analog supply (VCC) and a +3.3V ±300mV power
supply connected to V CCO for the logic outputs.
Bypass each of the VCC_ supply pins to its respective
GND with high-quality ceramic capacitors located as
close to the package as possible (Table 2). Consult the
evaluation kit manual for a suggested layout and
bypassing scheme.
Table 2. Bypassing
10
SUPPLY
FUNCTION
VCC/
VCCO
BYPASS
TO
GND/
OGND
CAPACITOR
VALUE
Analog Inputs
6
7
0.01µF
Oscillator/Clock
8
11
0.01µF
0.01µF
Converter
13
12
Digital Q-Output
26
27
47pF
Digital I-Output
28
27
47pF
Buffer
36
19
0.01µF
______________________________________________________________________________________
Low-Power, 90Msps, Dual 6-Bit ADC
MAX1003
__________________Pin Configuration
TOP VIEW
GAIN 1
36 VCC
IOCC+ 2
35 DI5
IOCC- 3
34 DI4
IIN+ 4
33 DI3
IIN- 5
32 DI2
MAX1003
31 DI1
VCC
6
GND
7
30 DI0
VCC
8
29 DCLK
TNK+
9
28 VCCO
TNK- 10
27 OGND
GND 11
26 VCCO
GND 12
25 DQ0
VCC 13
24 DQ1
QIN- 14
23 DQ2
QIN+ 15
22 DQ3
QOCC- 16
21 DQ4
QOCC+ 17
20 DQ5
GND 18
19 GND
SSOP
___________________Chip Information
TRANSISTOR COUNT: 6097
______________________________________________________________________________________
11
________________________________________________________Package Information
SSOP2.EPS
MAX1003
Low-Power, 90Msps, Dual 6-Bit ADC
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
12 __________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 (408) 737-7600
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