MAX2108CEG(1999) Ver la hoja de datos (PDF) - Maxim Integrated
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MAX2108CEG Datasheet PDF : 12 Pages
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Direct-Conversion Tuner IC
_______________Detailed Description
The MAX2108 downconverts signals in the 950MHz to
2150MHz range directly to baseband in-phase/
quadrature-phase (I/Q) signals. It is designed for digital
DBS tuner applications where a direct downconversion
provides a cost savings over multiple-conversion
approaches. However, the MAX2108 is applicable to
any system requiring a broadband I/Q downconversion.
Internally, the MAX2108 consists of a broadband front-
end variable gain stage, a quadrature downconverter,
a 90° quadrature generator, a divide-by 32/33
prescaler, and high-linearity I and Q baseband buffers.
The front-end gain-control range is over 50dB.
Specifically, when the MAX2108 operates in an auto-
matic gain control (AGC) loop, VGC is adjusted by the
loop so that a sine wave at RFIN ranging in power from
-70dBm to -20dBm produces a sine wave across IOUT,
IOUT and QOUT, QOUT at 10mVp-p differential. The
noise figure is at its minimum when GC is at its maxi-
mum gain setting.
The quadrature downconverter follows the front-end
variable-gain amplifier. The mixer LO ports are fed with
the two LO signals, which are 90° apart in phase.
These quadrature LO signals are generated internally
using the signal from the LO and LO pins.
The resulting I/Q baseband signals are fed through
separate I-channel and Q-channel baseband buffers.
The outputs are capable of driving lowpass filters with
100Ω characteristic impedance (that is, the equivalent
of an AC-coupled 100Ω load). The baseband -3dB out-
put bandwidth is approximately 150MHz.
Applications Information
Front-End Tuner Circuitry
for DBS Tuners
In a typical application, the signal path ahead of the
tuner includes a discrete low-noise amplifier/buffer and
a PIN-diode attenuator. Since the MAX2108 satisfies
the noise and linearity requirements for DBS, this front-
end circuitry is not required.
In some very high linearity applications, such as single
channel-per-carrier (SCPC), a varactor-tuned pre-
selection bandpass filter is added between a discrete
LNA and the MAX2108. The filter provides a means of
broadly filtering adjacent interference signals, thus
improving the intermodulation performance of the tuner.
Additionally, the filter removes RF interference at twice
the LO frequency, which otherwise adds to the co-
channel interference. The MAX2108 rejects this carrier
to approximately 25dBc.
LO Port
The MAX2108 accepts either a single-ended or differ-
ential LO signal. For single-ended drive, AC-couple the
LO signal into LO with a 47pF capacitor, and bypass
LO to ground with a 47pF capacitor in series with a
25Ω resistor. Drive LO with a 50Ω source at -5dBm.
Prescaler
The prescaler requires a stable logic level at PS_SEL
4ns before the falling edge of PSOUT, PSOUT to assert
the desired modulus. The logic level at PS_SEL must
remain static until 2ns after this falling edge.
Baseband Buffers
The MAX2108 baseband buffers provide at least
10mVp-p differential swing across IOUT, IOUT and
QOUT, QOUT, and are capable of driving an AC-cou-
pled 100Ω differential load. In a typical application,
IOUT, IOUT, QOUT, and QOUT drive a 5th- or 7th-order
lowpass filter for ADC anti-aliasing purposes (see the
Filters in Direct-Conversion Tuners section ). In general,
additional gain is required, after the filters. This is
accomplished with a pair of video-speed op amps,
such as the MAX4216 dual video op amp, or a simple
transistor circuit. Contact Maxim for more information
about the MAX4216.
Layout Considerations
Observe standard RF layout rules. A ground plane is
essential; when connecting areas of ground plane
between layers, use vias liberally. If a ground plane is
used under the lowpass filters, note that the filter
response may be slightly offset due to parasitic capaci-
tance.
In a direct-conversion receiver, LO leakage to the RF
input connector is a major issue, since filtering of the
LO is impossible (the LO operates at the same frequen-
cy as the RF input). Observe the power-supply bypass
capacitor connections in the Pin Description table,
notably pins 3, 5, 12, and 21. Traces from these IC pins
to the bypass capacitors must be kept on the top side
of the board and as short as possible.
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