Micrel MICRF022BM Qwikradiotm low power uhf receiver preliminary information Datasheet

MICRF002 / 022
QwikRadiotm Low Power UHF Receiver
Preliminary Information
General Description
The MICRF002, an enhanced version of the MICRF001 and MICRF011,
is a single chip OOK (ON-OFF Keyed) Receiver IC for remote wireless
applications, employing Micrel’s latest QwikRadiotm technology. This
device is a true “antenna-in, data-out” monolithic device. All RF and IF
tuning is accomplished automatically within the IC, which eliminates
manual tuning and reduces production costs. Receiver functions are
completely integrated. The result is a highly reliable yet extremely low
cost solution for high volume wireless applications. Because the
MICRF002 is a true single-chip radio receiver, it is extremely easy to
apply, minimizing design and production costs, and improving time to
market.
The MICRF002 provides two fundamental modes of operation, FIXED
and SWP. In FIXED mode, the device functions like a conventional
superheterodyne receiver, with an (internal) local oscillator fixed at a
single frequency based on an external reference crystal or clock. As with
any conventional superheterodyne receiver, the transmit frequency must
be accurately controlled, generally with a crystal or SAW (Surface
Acoustic Wave) resonator.
In SWP mode, the MICRF002 sweeps the (internal) local oscillator at
rates greater than the baseband data rate. This effectively “broadens”
the RF bandwidth of the receiver to a value equivalent to conventional
super-regenerative receivers. Thus the MICRF002 can operate with less
expensive LC transmitters without additional components or tuning, even
though the receiver topology is still superheterodyne. In this mode the
reference crystal can be replaced with a less expensive ± 0.5% ceramic
resonator.
The MICRF002 provides two feature enhancements over the
MICRF001/011, (1) a Shutdown Mode, which may be used for dutycycle operation, and (2) a “Wakeup” function, which provides a logical
indication of an incoming RF signal. These features make the
MICRF002 ideal for low and ultra-low power applications, such as RKE
and RFID.
All post-detection (demodulator) data filtering is provided on the
MICRF002, so no external filters need to be designed. Any one of four
filter bandwidths may be selected externally by the user. Bandwidths
range in binary steps, from 0.625kHz to 5kHz (SWP mode) or 1.25kHz to
10kHz (FIXED mode). The user only needs to program the appropriate
filter selection based on data rate and code modulation format.
Features
•
•
•
•
•
•
•
•
•
•
•
•
Complete UHF receiver on a monolithic chip
Frequency range 300 to 440 MHz
Typical range over 200 meters with monopole
antenna
Data rates to 2.5kbps (SWP), 10kbps (FIXED)
Automatic tuning, no manual adjustment
No Filters or Inductors required
Low Operating Supply Current—240 µA at 315MHz
(10:1 Duty Cycle)
Shutdown Mode for Duty-Cycle Operation in excess
of 100:1
Wakeup Function to Enable External Decoders and
Microprocessors
Very low RF re-radiation at the antenna
CMOS logic interface to standard decoder and
microprocessor ICs
Extremely low external part count
Applications
•
•
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Automotive Remote Keyless Entry
Long Range RFID
Remote Fan/Light Control
Garage Door/Gate Openers
Typical Operating Circuit
385.5 MHz, 1200 bps OOK RECEIVER
Micrel Inc. • 1849 Fortune Drive San Jose, Ca 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 944-0970 • http://www.micrel.com
MICRF002
QwikRadio
tm
Micrel
Ordering Information
Part Number
MICRF002BN
MICRF002BM
MICRF022BN
MICRF022BM
Temperature Range
-40°C to +85°C
-40°C to +85°C
-40°C to +85°C
-40°C to +85°C
Package
16-Pin DIP
16-Pin SOIC
8-Pin DIP
8-Pin SOIC
The standard 16-pin package provides the user with complete control of MICRF002 mode and filter selection. An 8-pin
standard part is also available for very low cost applications. The 8-pin version comes pre-programmed in SWP mode, with
Demodulator Filter bandwidth set to 5000Hz, and SHUT pin externally available. Other 8-pin configurations are available.
Contact the factory for details.
Pin Configuration (DIP and SOIC)
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Pin Description (Pin numbers for the 8-pin version are identified in parentheses)
Pin Number
Pin Name
1
SEL0
2/3
VSSRF
(1)
VSS
4
(2)
ANT
5
VDDRF
6
VDDBB
(3)
VDD
7
(4)
CTH
8
9
N/C
VSSBB
10
(5)
11
DO
SHUT
(6)
12
WAKEB
13
(7)
CAGC
14
SEL1
15
(8)
REFOSC
16
SWEN
SEL0
1
0
1
0
Pin Function
This pin, in conjunction with SEL1, programs the desired Demodulator Filter Bandwidth. This pin is
internally pulled-up to VDD. See Table 1.
This pin is the ground return for the RF section of the IC. The bypass capacitor connected from VDDRF to
VSSRF should have the shortest possible lead length. For best performance, connect VSSRF to VSSBB
at the power supply only (i.e., keep VSSBB currents from flowing through VSSRF return path).
This pin is the ground return for the IC. The bypass capacitor connected from VDD to VSS should have
the shortest possible lead length.
This is the receive RF input, internally ac-coupled. Connect this pin to the receive antenna. Input
impedance is high (FET gate) with approximately 2pF of shunt (parasitic) capacitance. For applications
located in high ambient noise environments, a fixed value band-pass network may be connected between
the ANT pin and VSSRF to provide additional receive selectivity and input overload protection. (See
“Application Note TBD”.)
This pin is the positive supply input for the RF section of the IC. VDDBB and VDDRF should be connected
directly at the IC pins. Connect a low ESL, low ESR decoupling capacitor from this pin to VSSRF, as short
as possible.
This pin is the positive supply input for the baseband section of the IC. VDDBB and VDDRF should be
connected directly at the IC pins.
This pin is the positive supply input for the IC. Connect a low ESL, low ESR decoupling capacitor from this
pin to VSSRF, as short as possible.
This capacitor extracts the (DC) average value from the demodulated waveform, which becomes the
reference for the internal data slicing comparator. Treat this as a low-pass RC filter with source impedance
of 118kΩ (for REFOSC frequency ft = 4.90MHz, see Note 5). A standard ± 20% X7R ceramic capacitor is
generally sufficient.
Unused Pin
This is the ground return for the baseband section of the IC. The bypass and output capacitors connected
to VSSBB should have the shortest possible lead lengths. For best performance, connect VSSRF to
VSSBB at the power supply only (i.e., keep VSSBB currents from flowing through VSSRF return path).
The output data signal. CMOS level compatible.
A logic input for Shutdown Mode control. Pull this pin low to place the IC into operation. This pin in
internally pulled-up to VDD.
An output signal, active low when the IC detects an incoming RF signal, determined by monitoring for data
preamble. CMOS level compatible.
Integrating capacitor for on-chip AGC (Automatic Gain Control). The Decay/Attack time-constant (TC) ratio
is nominally set as 10:1. Use of 0.47uF or greater is strongly recommended for best range performance.
Use low-leakage type capacitors for duty-cycle operation (Dip Tantalum, Ceramic, Polyester). (See
“Application Note TBD.)
This pin, in conjunction with SEL0, programs the desired Demodulator Filter Bandwidth. This pin in
internally pulled-up to VDD. See Table 1.
This is the timing reference for on-chip tuning and alignment. Connect either a ceramic resonator or crystal
(mode dependent) between this pin and VSSBB, or drive the input with an AC coupled 0.5Vpp input clock.
Use ceramic resonators without integral capacitors. Note that if operating in FIXED mode, a crystal must
be used; however in SWP mode, one may use either a crystal or ceramic resonator. See “Application Note
TBD” for details on frequency selection and accuracy.
This logic pin controls the operating mode of the MICRF002. When SWEN = HIGH, the MICRF002 is in
SWP mode. When SWEN = LOW, the device operates as a conventional single-conversion
superheterodyne receiver. (See “Application Note TBD” for details.) This pin is internally pulled-up to VDD.
SEL1
1
1
0
0
Demodulator Bandwidth (Hz)
SWP Mode
5000
2500
1250
625
FIXED Mode
10000
5000
2500
1250
Table 1
Nominal Demodulator (Baseband) Filter Bandwidth
vs. SEL0, SEL1 and Mode
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ABSOLUTE MAXIMUM RATINGS
Operating Ratings
Supply Voltage (VDDRF, VDDBB)..................................+7V
Voltage on any I/O Pin........................VSS-0.3 to VDD+0.3
Junction Temperature..............................................+150°C
Storage Temperature Range....................-65°C to + 150°C
Lead Temperature (soldering, 10 seconds)..............+ 260°C
Supply Voltage (VDDRF, VDDBB)..................4.75V to 5.5V
Ambient Operating Temperature (TA)............-40°C to +85°C
Package Thermal Resistance θJA (16 Pin DIP).........90°C/W
Package Thermal Resistance θJA (16 Pin SOIC)....120°C/W
This device is ESD sensitive: Meets Class 1ESD
test requirements (Human body Model, HBM), in
accordance with MIL-STD-883C, Method 3015. Do
not operate or store near strong electrostatic
fields.
Use appropriate ESD precautions.
Electrical Characteristics
Unless otherwise stated, these specifications apply for Ta = -40°C to 85°C, 4.75<VDD<5.5V. All voltages are with respect to
Ground; Positive currents flow into device pins. CAGC = 4.7µF, CTH = .047µF, VDDRF= VDDBB = VDD. REFOSC
frequency = 4.90MHz.
Parameter
Test Conditions
MIN
TYP
MAX
UNITS
Power Supply
Operating Current
Continuous Operation
2.4
mA
Operating Current
10:1 Duty Cycle
240
µA
Standby Current
SHUT = VDD
0.5
µA
RF/IF Section
Receiver Sensitivity
Note 1, 3
-103
dBm
IF Center Frequency
Note 4
0.86
MHz
IF 3dB Bandwidth
Note 3, 4
0.43
MHz
RF Input Range
300
Receive Modulation Duty-Cycle
20
Maximum Receiver Input
Spurious Reverse Isolation
440
MHz
80
%
Rsc = 50Ω
-20
dBm
ANT pin, Rsc = 50Ω Note 2
30
µVrms
AGC Attack / Decay ratio
T(Attack) / T(Decay)
0.1
AGC Leakage Current
Ta = 85°C
Local Oscillator Stabilization Time
To 1% of Final Value
±100
nA
2.5
msec
Demod Section
CTH Source Impedance
Note 5
Ω
118k
CTH Source Impedance Variation
-15
+15
%
CTH Leakage Current
Ta = 85°C
±100
nA
Demod Filter Bandwidth
SEL0 = SEL1 = SWEN = VDD, Note 4, 6
4160
Hz
Demod Filter Bandwidth
SEL0 = SEL1 = VDD, SWEN = VSS
Note 4, 6
8320
Hz
200k
Ω
8
µA
Digital/Control Section
REFOSC Input Impedance
Input Pull up Current
SEL0, SEL1, SWEN, SHUT=VSS
Input High Voltage
SEL0, SEL1, SWEN
Input Low Voltage
SEL0, SEL1, SWEN
Output Current
DO, WAKEUP pins, Push-Pull
Output High Voltage
DO, WAKEUP pins, Iout = -1µA
Output Low Voltage
DO. WAKEUP pins, Iout = +1µA
0.1VDD
V
Output Tr, Tf
DO, WAKEUP pins, Cload=15pF
10
µsec
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0.8VDD
0.2VDD
4
V
V
10
µA
0.9VDD
V
MICRF002
MICRF002
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
Note 6:
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Sensitivity is defined as the average signal level measured at the input necessary to achieve 10e-2 Bit Error Rate (BER). The
input signal is defined as a return-to-zero (RZ) waveform with 50% average duty cycle (e.g., Manchester Encoded Data) at a
data rate of 300bps. The RF input is assumed to be matched into 50Ω.
Spurious reverse isolation represents the spurious components which appear on the RF input (ANT) pin measured into 50Ω
with an input RF matching network.
Sensitivity, a commonly specified Receiver parameter, provides an indication of the Receiver’s input referred noise, generally
input thermal noise. However, it is possible for a more sensitive receiver to exhibit range performance no better than that of a
less sensitive receiver, if the “ether” noise is appreciably higher than the thermal noise. “Ether” noise refers to other interfering
“noise” sources, such as FM radio stations, pagers, etc.
A better indicator of achievable receiver range performance is usually given by its Selectivity, often stated as Intermediate
Frequency (IF) or Radio Frequency (RF) bandwidth, depending on receiver topology. Selectivity is a measure of the rejection
by the receiver of “ether” noise. More selective receivers will almost invariably provide better range. Only when the receiver
selectivity is so high that most of the noise on the receiver input is actually thermal will the receiver demonstrate sensitivitylimited performance.
Parameter scales linearly with REFOSC frequency ft. For any REFOSC frequency other than 4.90MHz, compute new
parameter value as the ratio [(REFOSC FREQ (in MHz) / 4.90] * [Parameter Value @ 4.90MHz]. Example: For REFOSC
Freq. ft = 6.00MHz, [Parameter Value @ 6.00MHz] = (6.00 / 4.90) * [Parameter Value @ 4.90MHz].
Parameter scales inversely with REFOSC frequency ft. For any REFOSC frequency other than 4.90MHz, compute new
parameter value as the ratio [4.90 / (REFOSC FREQ (in MHz)] * [Parameter Value @ 4.90MHz]. Example: For REFOSC
Freq. ft = 6.00MHz, [Parameter Value @ 6.00MHz] = (4.90 / 6.00) * [Parameter Value @ 4.90MHz].
Demod filter bandwidths are related in a binary manner, so any of the (lower) nominal filter values may be derived simply by
dividing this parameter value by 2, 4, or 8 as desired.
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Typical Performance Characteristics
MICRF002 IDD vs Frequency
(Temperature=25°°C, VDD=5.0V, SWP Mode, Continuous Operation)
6.10
5.60
5.10
4.60
4.10
IDD(mA)
3.60
3.10
2.60
2.10
1.60
250
275
300
325
350
375
400
425
450
475
500
Frequency (MHz)
MICRF002 IDD vs Temperature
(Frequency=315MHz, VDD=5.0V, SWP Mode, Continuous Operation)
3.30
3.10
2.90
2.70
IDD(mA)
2.50
2.30
2.10
1.90
-40
-20
0
20
40
60
85
Temperature (C)
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MICRF002 Block Diagram
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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.
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.
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.
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.
th
Rolloff response of the IF Filter is 5 order, while the
nd
demodulator data filter exhibits a 2
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”.
[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.
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.
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 crystalbased 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.]
For applications where the transmit frequency is accurately
set for other reasons (e.g., applications where a SAW
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(or otherwise limited) to approximately 0.5Vpp. The specific
reference frequency required is related to the system
transmit frequency, and to the operating mode of the device
as set by the SWEN control pin. See “Application Note
TBD” for a discussion of frequency selection and accuracy
requirements.
AGC Function and the CAGC Capacitor
The signal path has automatic gain control (AGC) to
increase input dynamic range.
An external capacitor,
CAGC, must be connected to the CAGC pin of the device.
The ratio of decay-to-attack time-constant is fixed at 10:1
(i.e., the attack time constant is 1/10th the decay time
constant), and this ratio cannot be changed by the user.
However, the attack time constant is selectable by the user
through the value of capacitor CAGC.
Wakeup Function
The Wakeup function is made available for the purposes of
further reducing power consumption of the overall wireless
system. WAKEB is an output logic signal, which goes active
when the IC detects a constant tone “header” in the
demodulated output signal. Sense of the signal is activelow. This output may be used to “wakeup” other external
circuits, like a data decoder or microprocessor, only at times
when there is a reasonable expectation of an incoming RF
signal. The Wakeup function is unavailable when the IC is
in SHUT mode.
[By adding resistance from the CAGC pin to VDDBB or
VSSBB in parallel with the CAGC capacitor, the ratio of
decay-to-attack time-constant may be varied, although the
value of such adjustments must be studied on a perapplication basis. Generally the design value of 10:1 is
adequate for the vast majority of applications.]
See
“Application Note TBD”.
To maximize system range, it is important to keep the AGC
control voltage ripple low, preferably under 10mVpp once
the control voltage has attained its quiescent value. For this
reason capacitor values ≥ 0.47uF are recommended.
The Wakeup function is composed of a resettable counter,
based on an internal 25kHz clock (based on a 6.4MHz
reference frequency). To utilize this function, a constant
tone in excess of about 4msec must be placed at the start of
each data code word, or a single 4msec tone at the start of
the data pattern (clearly the former is preferred to improve
communication reliability). When this constant tone is
detected, without interruption, for 128 clock cycles of 25kHz,
WAKEB will transition low, and stay low until data begins.
This particular approach is utilized over others (1) since
constant tones in excess of 4msec are very rare, leading to
few false-positive indications, and (2) this technique does
not require the introduction of a signal path offset, which
impacts achievable range.
The AGC control voltage is carefully managed on-chip to
allow duty-cycle operation of the MICRF002 in excess of
100:1. When the device is placed into SHUT mode (i.e.,
SHUT pin pulled high), the AGC capacitor is “floated”, to
retain the voltage. When operation is resumed, only the
voltage droop on the capacitor associated with leakage must
be replenished. Thus a relatively low-leakage capacitor is
recommended for duty cycle operation. The actual tolerable
leakage will be application dependent. Clearly, leakage
performance is less critical when the device off-time is low
(milliseconds), and more critical when the off-time is high
(seconds).
[Note: For designers who wish to use the Wakeup function
while “squelching” the output, a positive squelching offset
voltage must be used. This simply requires the squelch
resistor be taken to a voltage more positive than the
quiescent voltage on pin CTH, so that the data output is low
in absence of a transmission.]
To further enhance Duty-cycle operation of the IC, the AGC
push and pull currents are increased for a fixed time
immediately after the device is taken out of Shutdown mode
(i.e., turned-on). This compensates for AGC capacitor
voltage “droop” while the IC is in Shutdown, reduces the
time to reacquire the correct AGC voltage, and thus extends
maximum achievable duty ratios. Push/Pull currents are
increased by 45X their nominal values. The fixed time
period is based on the REFOSC frequency ft, 10.9msec for
ft = 6.00MHz, and varies inversely as ft varies.
Shutdown Function
The Shutdown function is controlled by the logic state of
SHUT. When SHUT is high, the device goes into low-power
standby mode, consuming less than 1µA. This pin is pulled
high internally, and so must be pulled low to engage the
device.
Reference Oscillator (REFOSC) and External Timing
Element
MICRF002 Frequency and Capacitor Selection
All timing and tuning operations on the MICRF002 are
derived from the REFOSC function. This function is a
single-pin Colpitts-type oscillator. The user may handle this
pin in one of three possible ways:
Selection of the REFOSC frequency ft, Slicing Level (CTH)
capacitor, and AGC capacitor are briefly summarized in this
section. Please see Application Note TBD for complete
details.
(1) connect a ceramic resonator, or
(2) connect a crystal, or
(3) drive this pin with an external timing signal.
The third approach is attractive for further lowering system
cost if an accurate reference signal exists elsewhere in the
system (e.g., a reference clock from a crystal or ceramic
resonator-based microprocessor). An externally applied
signal should be AC-coupled, and resistively-divided down
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1. Selecting REFOSC Frequency ft (FIXED Mode)
Assuming that a Slicing Level Timeconstant TC has been
established, capacitor CTH may be computed using
equation (5):
As with any superheterodyne receiver, the difference
between the (internal) Local Oscillator (LO) frequency flo
and the incoming Transmit frequency ftx must ideally equal
the IF Center frequency. Equation (1) may be used to
compute the appropriate flo for a given ftx:
flo = ftx ± 1.064 * (ftx / 390)
CTH = TC / Rsc.
4. Selecting CAGC Capacitor in Continuous Mode
(1)
Selection of CAGC is dictated by minimizing the ripple on
the AGC control voltage, by using a sufficiently large
capacitor. It is Micrel’s experience that CAGC should be in
the vicinity of 0.47µF to 4.7µF. Large capacitor values
should be carefully considered, as this determines the time
required for the AGC control voltage to settle from a
completely discharged condition. AGC settling time from a
completely discharged (0-volt) state is given approximately
by equation (6):
where ftx and flo are in MHz. Note that two values of flo
exist for any given ftx, distinguished as “high-side mixing”
and “low-side mixing”, and there is generally no preference
of one over the other.
After choosing one of the two acceptable values of flo, use
equation (2) to compute the REFOSC frequency ft:
ft = flo / 64.5.
(5)
(2)
Here ft is in MHz. Connect a crystal of frequency ft to the
REFOSC pin of the MICRF002. 4 decimal-place accuracy
on the frequency is generally adequate. The following table
identifies ft for some common Transmit frequencies when
the MICRF002 is operated in FIXED mode.
∆T = (1.333 * CAGC) – 0.44
Transmit Freq. ftx (MHz)
Generally, droop of the AGC control voltage during
shutdown should be replenished as quickly as possible after
the IC is “turned-on”. Recall from the section “AGC
Function and the CAGC Capacitor” that for about 10msec
after the IC is turned-on, the AGC push-pull currents are
increased to 45X their normal values. So consideration
should be given to selecting a value for CAGC and a
shutdown time period such that the droop can be
replenished within this 10msec period.
2.
where CAGC is in microfarads, and ∆T is in seconds.
5. Selecting CAGC Capacitor in Duty-Cycle Mode
REFOSC Freq. ft (MHz)
315
418
433.92
4.8970
6.4983
6.7458
Selecting REFOSC Frequency ft (SWP Mode)
Selection of REFOSC frequency ft in SWP mode is much
simpler than in FIXED mode, due to the LO sweeping
process. Further, accuracy requirements of the frequency
reference component are significantly relaxed.
Polarity of the droop is unknown, meaning the AGC voltage
could droop up or down. Worst-case from a recovery
standpoint is downward droop, since the AGC pullup current
th
is 1/10 magnitude of the pulldown current. The downward
droop is replenished according to the well-known equation
(7):
In SWP mode, ft is given by equation (3):
ft = ftx / 64.25.
(6)
(3)
I / CAGC = ∆V / ∆T
Connect a ceramic resonator of frequency ft to the REFOSC
pin of the MICRF002. 2-decimal place accuracy is generally
adequate. (A crystal may also be used if desired, but may
be necessary to reduce the Rx frequency ambiguity if the Tx
frequency ambiguity is excessive. See Application Note
TBD for further details.)
(7)
where I = AGC Pullup current for initial 10msec (67.5µA),
CAGC is the AGC capacitor value, ∆T = Droop recovery time
(<10msec), and ∆V is the droop voltage.
For example, if user desires ∆T = 10msec, and chooses a
4.7µF CAGC, then the allowable droop is about 144mV.
Using the same equation with 200nA worst case pin leakage
and assuming 1uA of capacitor leakage in the same
direction, the maximum allowable ∆T (Shutdown time) is
about 0.56 seconds, for droop recovery in 10msec.
3. Selecting Capacitor CTH
First step in the process is selection of a Data Slicing Level
timeconstant. This selection is strongly dependent on
system issues, like system decode response time and data
code structure (e.g., existence of data preamble, etc.). This
issue is too broad to discuss here, and the interested reader
should consult the Application Note 22.
Source impedance of the CTH pin is given by equation (4),
where ft is in MHz:
Rsc = 118kΩ * (4.90 / ft).
July 1999
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MICRF002
MICRF002
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I/O Pin Interface Circuitry
3. CAGC Pin
Interface circuitry for the various I/O pins of the MICRF002 is
shown in Figures 1 through 6.
Specific information
regarding each of these circuits is discussed in the following
sub-paragraphs. Not shown are ESD protection diodes
which are applied to all input and output pins.
Figure 3 illustrates the CAGC pin interface circuit. The AGC
control voltage is developed as an integrated current into a
capacitor CAGC. The attack current is nominally 15µA,
while the decay current is a 1/10th scaling of this, nominally
1.5µA, so the attack/decay timeconstant ratio is fixed at
10:1. Signal gain of the RF/IF strip inside the IC diminishes
as the voltage on CAGC decreases. Further discussion on
setting the attack time constant is found in “Application Note
TBD. Modification of the attack/decay ratio is possible by
adding resistance from CAGC pin either to VDDBB or
VSSBB, as desired.
1. ANT Pin
Both the Push and Pull current sources are disabled during
SHUT, which holds the voltage across CAGC, and improves
recovery time in duty-cycled applications.
To further
improve duty cycle recovery, both Push and Pull currents
are increased by 45X for approximately 10msec after
release of SHUT. This allows rapid recovery of any voltage
droop on CAGC while in SHUT.
4. DO and WAKEB Output Pins
Figure 1 ANT Pin
The output stage for the signals DO and WAKEB is shown in
Figure 4. The output is a 10µA push-10µA pull, switched
current stage. Such an output stage is capable of driving
CMOS-type loads.
An external buffer-driver is
recommended for driving high capacitance loads.
The ANT pin is internally AC-coupled via a 3pF capacitor, to
an RF N-channel MOSFET, as shown in Figure 1.
Impedance on this pin to VSS is quite high at low
frequencies, and decreases as frequency increases. In the
UHF frequency range, the device input can be modeled as
6.3kΩ in parallel with 2pF (pin capacitance) shunt to
VSSRF.
5. REFOSC Pin
The REFOSC input circuit is shown in Figure 5. Input
impedance is quite high (200kΩ).
This is a Colpitts
oscillator, with internal 30pF capacitors. This input is
intended to work with standard ceramic resonators,
connected from this pin to VSSBB, although a crystal may
be used instead, where greater frequency accuracy is
required.
The resonators should not contain integral
capacitors, since these capacitors are contained inside the
IC.
Externally applied signals should be AC-coupled,
amplitude limited to approximately 0.5Vpp. The nominal DC
bias voltage on this pin is 1.4V.
2. CTH Pin
Figure 2 illustrates the CTH pin interface circuit. CTH pin is
driven from a P-channel MOSFET source-follower biased
with approximately 10µA of bias current. Transmission
gates TG1 and TG2 isolate the 6.9pF capacitor. Internal
control signals PHI1/PHI2 are related in a manner such that
the impedance across the transmission gates looks like a
“resistance” of approximately 100kΩ. The DC potential on
the CTH pin is approximately 1.6V
6. Control Inputs (SEL0, SEL1, SWEN, SHUT)
Control input circuitry is shown in Figures 6a and 6b. The
standard input is a logic inverter constructed with minimum
geometry MOSFETs (Q2, Q3). P-channel MOSFET Q1 is a
large channel length device which functions essentially as a
“weak” pullup to VDDBB. Typical pullup current is 5µA,
leading to an impedance to the VDDBB supply of typically
1MΩ.
July 1999
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MICRF002
MICRF002
QwikRadio
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Micrel
Figure 3 CAGC Pin
Figure 2 CTH Pin
Figure 5 REFOSC Pin
Figure 4 DO and WAKEB Pins
Figure 6b SHUT
Figure 6a SEL0, SEL1, SWEN
July 1999
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MICRF002
MICRF002
QwikRadio
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Micrel
Typical Application
Figure 7 below illustrates a typical application for the MICRF002 UHF Receiver IC. Operation in this example is at 385.5MHz,
and may be customized by selection of the appropriate reference frequency (CR1), and adjustment of the antenna length.
The value of C4 would also change, if the optional input filter is used. Changes from the 1kbps data rate may require a
change in the value of R1. The Bill of Materials is shown in the accompanying chart.
Figure 7
385.5MHz, 1kbps OOK Receiver/Decoder
SWP Mode, Continuous Operation
6-Bit Address Decode/2 OP Codes
Bill of Materials
Item
U1
U2
CR1
D1
R1
R2
C1
C3
C2
C4
Part Number
MICRF002
HT-12D
CSA6.00MG
SSF-LX100LID
Manufacturer
Micrel
Holtek
Murata
Lumex
Bourns
Bourns
Panasonic
Panasonic
Panasonic
Panasonic
Vendor
Bourns
Holtek
Lumex
Murata
Panasonic
Description
UHF Receiver
Logic decoder
6.00MHz Cer. Res.
Red LED
68k, 1/4W ,5%
1k,1/4W, 5%
4.7µF, Dip Tant. Cap
0.47µF, Dip Tant. Cap
2.2µF, Dip Tant. Cap
8.2pF, COG Cer. Cap
Telephone
(909) 781-5500
(408) 894-9046
(800) 278-5666
(800) 241-6574
(201) 348-7000
Fax
(909) 781-5273
(408) 894-0838
(847) 359-8904
(770) 436-3030
(201) 348-8164
MICREL INC. 1849 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL
+ 1 (408) 944-0800
FAX
+ 1 (408) 944-0970
WEB
http://www.micrel.com
This information is believed to be accurate and reliable, however no responsibility is assumed by Micrel for its use nor for any infringement of patents or other rights
of third parties resulting from its use. No license is granted by implication or otherwise under any patent or patent right of Micrel Inc. This is preliminary
information and a final specification has not been completed. Before making any final design determination, consult with Micrel for final specifications.
©1998 Micrel Incorporated
July 1999
13
MICRF002
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