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MAX1185 Datasheet, PDF (14/20 Pages) Maxim Integrated Products – Dual 10-Bit, 20Msps, +3V, Low-Power ADC with Internal Reference and Multiplexed Parallel Outputs
Dual 10-Bit, 20Msps, +3V, Low-Power ADC with
Internal Reference and Multiplexed Parallel Outputs
Table 1. MAX1185 Output Codes For Differential Inputs
DIFFERENTIAL INPUT
VOLTAGE*
VREF x 511/512
VREF x 1/512
0
- VREF x 1/512
-VREF x 511/512
-VREF x 512/512
*VREF = VREFP - VREFN
DIFFERENTIAL
INPUT
+FULL SCALE - 1LSB
+ 1 LSB
Bipolar Zero
- 1 LSB
- FULL SCALE + 1 LSB
- FULL SCALE
STRAIGHT OFFSET
BINARY
T/B = 0
11 1111 1111
10 0000 0001
10 0000 0000
01 1111 1111
00 0000 0001
00 0000 0000
TWO’S COMPLEMENT
T/B = 1
01 1111 1111
00 0000 0001
00 0000 0000
11 1111 1111
10 0000 0001
10 0000 0000
Single-Ended AC-Coupled Input Signal
Figure 7 shows an AC-coupled, single-ended applica-
tion. Amplifiers like the MAX4108 provide high speed,
high bandwidth, low noise, and low distortion to maintain
the integrity of the input signal.
Typical QAM Demodulation Application
The most frequently used modulation technique for digital
communications applications is probably the Quadrature
Amplitude Modulation (QAM). Typically found in spread-
spectrum based systems, a QAM signal represents a
carrier frequency modulated in both amplitude and
phase. At the transmitter, modulating the baseband sig-
nal with quadrature outputs, a local oscillator followed by
subsequent up-conversion can generate the QAM signal.
The result is an in-phase (I) and a quadrature (Q) carrier
component, where the Q component is 90 degree phase-
shifted with respect to the in-phase component. At the
receiver, the QAM signal is divided down into it’s I and Q
components, essentially representing the modulation
process reversed. Figure 8 displays the demodulation
process performed in the analog domain, using the dual
matched +3.3V, 10-bit ADC MAX1185 and the MAX2451
quadrature demodulator to recover and digitize the I and
Q baseband signals. Before being digitized by the
MAX1185, the mixed down-signal components may be fil-
tered by matched analog filters, such as Nyquist or
Pulse-Shaping filters. These remove any unwanted
images from the mixing process, thereby enhancing the
overall signal-to-noise (SNR) performance and minimizing
intersymbol interference.
Grounding, Bypassing, and
Board Layout
The MAX1185 requires high-speed board layout design
techniques. Locate all bypass capacitors as close to
the device as possible, preferably on the same side as
the ADC, using surface-mount devices for minimum
inductance. Bypass VDD, REFP, REFN, and COM with
two parallel 0.1µF ceramic capacitors and a 2.2µF
bipolar capacitor to GND. Follow the same rules to
bypass the digital supply (OVDD) to OGND. Multilayer
boards with separated ground and power planes pro-
duce the highest level of signal integrity. Consider the
use of a split ground plane arranged to match the
physical location of the analog ground (GND) and the
digital output driver ground (OGND) on the ADC’s
package. The two ground planes should be joined at a
single point such that the noisy digital ground currents
do not interfere with the analog ground plane. The ideal
location of this connection can be determined experi-
mentally at a point along the gap between the two
ground planes, which produces optimum results. Make
this connection with a low-value, surface-mount resistor
(1Ω to 5Ω), a ferrite bead, or a direct short. Alternatively,
all ground pins could share the same ground plane, if
the ground plane is sufficiently isolated from any noisy
digital systems ground plane (e.g., downstream output
buffer or DSP ground plane). Route high-speed digital
signal traces away from the sensitive analog traces of
either channel. Make sure to isolate the analog input
lines to each respective converter to minimize channel-
to-channel crosstalk. Keep all signal lines short and
free of 90 degree turns.
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