On Sep 4, 2007, at 8:03 AM, Shawn Rutledge wrote:
On 9/4/07, Richi Plana <[EMAIL PROTECTED]> wrote:
Fascinating. So "passive receivers" really aren't? Or are there
classes
of receivers which are (no amplification or very sensitive pickups)?
In theory nowadays DSPs are fast enough to process the lower bands of
radio signals directly off-the-air with no IF, but I'm not sure if
anybody's doing that yet. Suspect the modern ham HF rigs might be
doing that, but haven't researched it. But a clock signal for any
digital system might also cause radiated interference, right? Radar
and GPS and GSM are all too high in frequency to handle that way, so
far.
John described heterodyne receivers, where the signal is first down-
converted to intermediate frequency (IF) for efficient channel
selection, and then filtered to remove interfering signals and
amplified for another step of down-conversion to the baseband
frequency. The heterodyne receiver provides good performance in terms
of channel selectivity and sensitivity, but with the need for off-
chip surface-acoustic wave (SAW) filters in combination with
additional IF circuitry. Since SAW filters are fabricated using
different material technology, they cannot be integrated with the IC.
To replace expensive SAW filters in the heterodyne receiver, another
approach is used- the low-IF architecture, where the RF signal is
converted to a very low IF frequency, and then filtered using passive
or active in-circuit filters. However, this architecture suffers from
poor performance in terms of image rejection and channel selectivity.
The direct conversion (or homodyne) receiver eliminates the
intermediate frequency stage, and directly down-converts the RF
signal to a baseband signal. Without the IF stage, bandpass filters
and other elements can be eliminated to reduce the bill of materials,
and therefore cost. Until quite recently, direct conversion issues
have frustrated RF engineers with inherent problems such as self-
mixing, 1/f noise and the resultant loss of sensitivity. Self-mixing
comes from the LO signal making its way to the input of the mixer,
which generates DC as a mixing product, possibly saturating the
following filters and gain amplifiers. The sensitivity problem and 1/
f noise have been solved by optimally controlling (normally via DSP
or a small CPU), a number of amplify-and-filter stages in the
receiver chain.
You likely have a direct-conversion receiver nearby right now. Its
your Wi-Fi card, unless you're still using 802.11b, or you've got an
Atheros card (but I don't want to go into that too deeply.) It was
explicitly the cost-reduction driver for BOM reduction which forced
the WiFi market to direct-conversion receivers.
Prolly off-topic, but I sure am curious. Are there no radar detectors
which don't give off their presence?
http://en.wikipedia.org/wiki/Radar_detector says that first radar
detector detector detectors were developed so the radar detector can
shut down when it detects that it's being detected; then they just
started using a lot of different IF's so the police can't monitor them
all. So modern radar detectors are mostly immune to detection.
Yes it's off-topic... will shut up now
Valentine One, there is no substitute.
Jim
