MICRF002BN 데이터 시트보기 (PDF) - Micrel
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MICRF002BN Datasheet PDF : 13 Pages
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MICRF002
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Micrel
Functional Description
Please refer to “MICRF002 Block Diagram”. Identified in the
block diagram are the four principal functional blocks of the
IC, namely (1) UHF Downconverter, (2) OOK Demodulator,
(3) Reference and Control, and (4) Wakeup. Also shown in
the figure are two capacitors (CTH, CAGC) and one timing
component (CR), usually a ceramic resonator. With the
exception of a supply decoupling capacitor, these are all the
external components needed with the MICRF002 to
construct a complete UHF receiver. Four control inputs are
shown in the block diagram, SEL0, SEL1, SWEN, and
SHUT. Through these logic inputs the user can control the
operating mode and selectable features of the IC. These
inputs are CMOS compatible, and are pulled-up on the IC.
Input SWEN selects the operating mode of the IC (FIXED
mode or SWP mode). When low, the IC is in FIXED mode,
and functions as a conventional superheterodyne receiver.
When SWEN is high, the IC is in SWP mode. In this mode,
while the topology is still superheterodyne, the local
oscillator (LO) is deterministically swept over a range of
frequencies at rates greater than the data rate. When
coupled with a peak-detecting demodulator, this technique
effectively increases the RF bandwidth of the MICRF002, so
the device can operate in applications where significant
Transmitter/Receiver frequency misalignment may exist.
[Note: The swept LO technique does not affect the IF
bandwidth, so noise performance is not impacted relative to
FIXED mode. In other words, the IF bandwidth is the same
(500kHz) whether the device is in FIXED or SWP mode.]
Due to limitations imposed by the LO sweeping process, the
upper limit on data rate in SWP mode is approximately
2.5kbps. Data rates beyond 10kbps are possible in FIXED
mode however.
transmitter is used for its mechanical stability), the user may
choose to configure the MICRF002 as a standard
superheterodyne receiver (FIXED mode), mitigating the
aforementioned problem of a competing close-in signal.
This can be accomplished by tying SWEN to ground. Doing
so forces the on-chip LO frequency to a fixed value. In
FIXED mode, the ceramic resonator would be replaced with
a crystal. Generally, however, the MICRF002 can be
operated in SWP mode, using a ceramic resonator , with
either LC or CRYSTAL/SAW based transmitters, without
any significant range difference.
The inputs SEL0 and SEL1 control the Demodulator filter
bandwidth in four binary steps (625Hz—5000Hz in SWP,
1250Hz—10000Hz in FIXED mode), and the user must
select the bandwidth appropriate to his needs.
Rolloff response of the IF Filter is 5th order, while the
demodulator data filter exhibits a 2nd order response.
Multiplication factor between the REFOSC frequency ft and
the internal Local Oscillator (LO) is 64.5X for FIXED mode,
and 64.25X for SWP mode (i.e., for ft = 6.00MHz in FIXED
mode, LO frequency = 6.00MHz * 64.5 = 387MHz).
Slicing Level and the CTH Capacitor
Extraction of the DC value of the demodulated signal for
purposes of logic-level data slicing is accomplished by
external capacitor CTH and the on-chip switched-cap
“resistor” RSC, indicated in the block diagram. The effective
resistance of RSC is 118kohms. The value of capacitor CTH
is easily calculated, once the slicing level time-constant is
chosen. Slicing Level time constant values vary somewhat
with decoder type, data pattern, and data rate, but typical
values range 5-50msec. Optimization of the CTH value is
required to maximize range, as discussed in “Application
Note TBD”.
Examples of SWP mode operation include applications
which utilize low-cost LC-based transmitters, whose transmit
frequency may vary up to ± 0.5% over initial tolerance,
aging, and temperature. In this (patent-pending) mode, the
LO frequency is varied in a prescribed fashion which results
in downconversion of all signals in a band approximately
1.5% around the transmit frequency. So the Transmitter
may drift up to ± 0.5% without the need to retune the
Receiver, and without impacting system performance. Such
performance is not achieved with currently available crystal-
based superheterodyne receivers, which can operate only
with SAW or crystal based transmitters.
[Note: In SWP mode only, a range penalty will occur in
installations where there exists a competing signal of
sufficient strength in this small frequency band of 1.5%
around the transmit frequency. This results from the fact
that sweeping the LO indiscriminately “sweeps” all signals
within the sweep range down into the IF band. This same
penalty also exists with super-regenerative type receivers,
as their RF bandwidth is also generally 1.5%. So any
application for a super-regenerative receiver is also an
application for the MICRF002 in SWP mode.]
During quiet periods (i.e., no signal transmissions) the Data
Output (DO pin) transitions randomly based on noise. This
may present problems for some decoders. The most
common solution is to introduce a small offset (“Squelch”)
on the CTH pin so that noise does not trigger the internal
comparator. Usually 20-30mV is sufficient, and may be
introduced by connecting a several-Megohm resistor from
the CTH pin to either VSS or VDD, depending on the desired
offset polarity. Since the MICRF002 is an AGC’d receiver,
noise at the internal comparator input is always the same,
set by the AGC. So the squelch offset requirement does not
change as the local “ether” noise changes from installation
to installation. Note that introducing squelch will reduce
range modestly, so only introduce an amount sufficient to
“quiet” the output.
For applications where the transmit frequency is accurately
set for other reasons (e.g., applications where a SAW
July 1999
8
MICRF002
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