MICRF007

MICRF007
Micrel
MICRF007
QwikRadio® Low-Power UHF Receiver
General Description
The MICRF007 is a single chip, ON-OFF Keyed (ASK/OOK)
Receiver for remote wireless applications, employing Micrel’s
latest QwikRadio® technology. This device is a true “antenna-in
to data-out” monolithic device. All RF and IF tuning is accomplished automatically within the IC, which eliminates manual
tuning, and reduces production costs. The result is a highly
reliable yet extremely low cost solution. The MICRF007 is an
enhanced version of the MICRF002 and MICRF011.
The MICRF007 is a conventional superhetrodyne receiver,
with an (internal) Local oscillator fixed at a single frequency
based on an external reference crystal or clock. As with any
conventional superhetrodyne receiver, the companion transmitter’s frequency must be accurately controlled, generally
with a crystal or SAW (surface acoustic wave) resonator.
The MICRF007 provides two enhancements over the MICRF001/011: (1) a Shutdown Mode, which may be used for
duty-cycle operation, and (2) reduced current consumption.
The MICRF007 requires a mere 2.3mA at 315MHz (3.8mA
at 433.92MHz) when fully operational. These features make
the MICRF007 ideal for low and ultra-low power applications,
such as RKE and RFID.
All post-detection (demodulator) data filtering is provided on
the MICRF007, so no external baseband filters are required.
The demodulator filter bandwidth is fixed at 2.5kHz. Data
rates up to 3.2kbps NRZ may be used.
All support documentation can be found on Micrel’s web site
at www.micrel.com.
QwikRadio®
Features
•
•
•
•
•
•
•
•
•
Complete UHF receiver on a monolithic chip
300MHz to 440MHz
Data rates up to 3.2kbps NRZ
Automatic tuning, no manual adjustment
Low power consumption
– 315MHz:
2.3 mA fully operational
0.5µA shutdown
230µA polled at a 10:1 duty cycle ratio
– 433.92MHz:
3.8mA fully operational
0.5µA shutdown
380µA polled at a 10:1 duty cycle ratio
Virtually no RF re-radiation at the antenna
CMOS logic interface to standard decoder and microprocessor ICs
Extremely low external part count
No filters or inductors required
Applications
•
•
•
•
Automotive remote keyless entry (RKE)
Long range RF identification
Remote fan and light control
Garage door and gate openers
Typical Application
50Ω�Ant
MICRF007
1.8pF
+5V
56nH
VSS
REFOSC
ANT
CAGC
VDD
SHUT
CTH
DO
0.039µF
4.8970MHz
2.2µF
Data
Output
315MHz 1200b/s On-Off Keyed Receiver
QwikRadio is a trademark of Micrel, Inc. The QwikRadio ICs were developed under a partnership agreement with AIT of Orlando, Florida.
Micrel, Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
February 17, 2005
1
M9999-021705
MICRF007
Micrel
Ordering Information
Part Number
Standard
Pb-Free
Junction Temp. Range
Package
MICRF007BM
MICRF007YM
–40°C to +85°C
8-pin SOIC
Pin Configuration
MICRF007BM
VSS 1
8 REFOSC
ANT 2
7 CAGC
VDD 3
6 SHUT
CTH 4
5 DO
8-Pin SOIC (M)
Pin Description
Pin Number
Pin Name
Pin Function
1
VSS
Ground: Signal and power ground.
2
ANT
Antenna (Analog Input): High-impedance, internally AC-coupled receiver
input. For optimal performance, the ANT pin should be impedance matched
to the antenna.
3
VDD
Power Supply (Input): Positive supply input. Connect a low ESL, low ESR
de-coupling capacitor from this pin to VSS. Lead lengths should be as short
as possible.
4
CTH
Data Slicing Threshold Capacitor (Analog I/O): Capacitor connected to this
pin extracts the DC average value from the demodulated waveform which
becomes the reference for the internal data slicing comparator.
5
DO
Data Output (Digital Output): CMOS-level compatible data output signal.
6
SHUT
Shutdown (Digital Input): Shutdown-mode logic-level control input. Pull low
to enable the receiver. Internally pulled-up to VDD.
7
CAGC
Automatic Gain Control (Analog I/O): Connect an external capacitor to set
the attack/decay ratio of the on-chip automatic gain control.
8
REFOSC
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Reference Oscillator: Timing reference, sets the RF receive frequency.
2
February 17, 2005
MICRF007
Micrel
Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage (VDD)..................................................... +7V
Input/Output Voltage (VI/O) ...................VSS–0.3 to VDD+0.3
Junction Temperature (TJ) ....................................... +150°C
Storage Temperature Range (TS) ............. –65°C to +150°C
Lead Temperature (soldering, 10 sec.) .................... +260°C
ESD Rating(3)
Supply Voltage (VDD)................................. +4.75V to +5.5V
RF Frequency Range ...........................300MHz to 440MHz
Data Duty-Cycle ............................................... 20% to 80%
Reference Oscillator Input range .............. 0.1VPP to 1.5VPP
Ambient Temperature (TA) .......................... –40°C to +85°C
Package Thermal Resistance
8-pin SOIC (θJA) ................................................ 120°C/W
Electrical Characteristics(4)
Power supply: +4.75V ≤ VDD ≤ 5.5V, VSS = 0V; CAGC = 4.7µF, CTH = 0.047µF; fT = 6.7458MHz (equivalent of fRF = 433.92MHz); datarate = 600bps (Manchester encoded). TA = 25°C, bold values indicate –40°C ≤ TA ≤ +85°C; current flow into device pins is positive;
unless noted.
Symbol
Parameter
Condition
IOP
Operating Current at 315.0MHz
Operating Current at 433.92MHz
ISTBY
Standby Current
fIF
IF Center Frequency
RF Section, IF Section
Receiver Sensitivity
fBW
Typ
Max
Units
continuous operation
2.3
3.5
mA
polled with 10:1 duty cycle
230
continuous operation
3.8
polled with 10:1 duty cycle
470
VSHUT = VDD
0.9
fRF = 433.92MHz, 1.2kbps
Note 7
IF Bandwidth
Notes 6, 7
Maximum Receiver Input
Ref. Impedance = 50Ω
0.4
Spurious Reverse Isolation
ANT pin, Ref. Impedance =
AGC Attack to Decay Ratio
tATTACK ÷ tDECAY
AGC Leakage Current
50Ω(8)
µA
5.7
mA
µA
2
µA
–99
dBm
1.18
MHz
0.70
MHz
–20
dBm
30
µVrms
10
TA = +85°C
±50
nA
to 1% of final value
2.5
ms
Reference Oscillator Input Impedance
290
kΩ
Reference Oscillator Source Current
5.2
µA
Reference Oscillator(9)
Reference Oscillator
Stabilization Time
ZREFOSC
Min
Demodulator
ZCTH
ΔZCTH
IZCTH(leak)
CTH Source Impedance
Note 10
CTH Leakage Current
TA = +85°C
±50
nA
2.5
kHz
VSHUT = VSS
8
µA
CTH Source Impedance Variation
Demodulator Filter Bandwidth
110
–15
Note 7
kΩ
+15
%
Digital/Control Section
IIN(pu)
Input Pull-Up Current
VIL
Input Low Voltage
VIH
Input High Voltage
February 17, 2005
VSHUT = VSS
VSHUT = VSS
3
0.8VDD
V
0.2VDD
V
M9999-021705
MICRF007
Symbol
Micrel
Parameter
Condition
Min
Typ
Max
Units
Output High Current
20.8
µA
IOL
Output Low Current
17.6
µA
VOL
Output Low Voltage
IOH
VOH
Output High Voltage
tR, tF
Output Rise and Fall Times
DO, IOUT = –1µA
DO, IOUT = +1µA
DO, CLOAD = 15pF
0.9VDD
V
10
0.1VDD
V
µs
Notes:
1. Exceeding the absolute maximum rating may damage the device.
2. The device is not guaranteed to function outside its operating rating.
3. Devices are E�
MIL-STD-883C, method 3015. Do not operate or store near strong electrostatic fields.
4. Specification for packaged product only.
5. Sensitivity is defined as the average signal level, measured at the input, necessary to achieve 10-2 BER (bit error rate). The input signal is defined
as a return-to-zero (RZ) waveform with 50% average duty cycle (Manchester encoded data) at a data rate of 600bps. The RF input is assumed to
be matched into 50Ω.
6. Sensitivity, a commonly specified receiver parameter, provides an indication of the receiver’s input referred noise, generally input thermal noise.
However, it is possibl�
noise is appreciab�
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 ambient noise. More selective
receivers will almost inva�
ally thermal will the receiver demonstrate sensitivity-limited performance.
7. Parameter scales linearly with reference oscillator frequency fT. For any reference oscillator frequency other than 6.7458MHz, compute the parameter value as the ratio:
fTMHz
6.7458
× (parameter value at 6.7458MHz)
Example: For reference oscillator freqency fT = 6.00MHz:
6.7458
(parameter value at 6.00MHz)=
× (parameter value at 6.7458MHz)
6.00
8. Spurious reve�
ing network.
-
9. Series resistance �
resistance is too great, the oscillator may oscillate at a diminished peak-to-peak level, or may fail to oscillate entirely. Micrel recommends that series
resistances for ceramic resonators and crystals not exceed 50Ω and 100Ω respectively. Refer to “Application Hint 35” for crystal recommendations.
10. Parameter scales inversely with reference oscillator frequency fT. For any reference oscillator frequency other than 6.7458MHz, compute the
parameter value as the ratio:
6.7458
fTMHZ
× (parameter value at 6.7458MHz)
Example: For reference oscillator frequency fT = 6.00MHz:
6.7458
× (parameter value at 6.7458MHz)
(parameter value at 6.00MHz) =
6.00
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February 17, 2005
MICRF007
Micrel
Typical Characteristics
Supply Current
vs. Frequency
6.0
T A = 25°C
V DD = 5V
3.5
Supply Current
vs. Temperature
f = 315MHz
V DD = 5V
Continuous Operation
3.0
4.5
2.5
3.0
2.0
Continuous Operation
1.5
300 325 350 375 400 425 450
FREQUENCY (MHz)
February 17, 2005
1.5
-40 -20
0
20
40
60
80 100
TEMPERATURE (°C)
5
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MICRF007
Micrel
Functional Diagram
CAGC
AGC
Control
CAGC
ANT
5th Order
Band-Pass Filter
RF
Amp
f RX
fIF
fLO
IF
Amp
IF
Amp
Peak
Detector
430kHz
2nd Order
Programmable
Low-Pass Filter
SwitchedCapacitor
Resistor
RSC
Comparator
VDD
UHF Downconverter
OOK Demodulator
CTH
Control
Logic
SHUT
REFOSC
Cystal
or
Ceramic
Resonator
CTH
Synthesizer
VSS
DO
fT
Reference
Oscillator
Reference and Control
MICRF007
MICRF007 Block Diagram
Applications Information and Functional
Description
Design Steps
The following steps are the basic design steps for using
the MICRF007 receiver:
1. Select the reference oscillator
2. Select the CTH capacitor
3. Select the CAGC capacitor
Refer to the functional diagram. Three sections of the IC are
identified: UHF Down-converter, OOK Demodulator and Reference and Control. Also shown are two capacitors (CTH,
CAGC) and one timing component (Y1), usually a crystal.
With the exception of a supply decoupling capacitor, these
are the only external components needed by the MICRF007
to assemble a complete UHF receiver.
For optimal performance, MICRF007 input impedance must
be matched to the antenna impedance. The matching network
will add an additional two or three components.
There is one control input, SHUT pin. The SHUT function is
used to enable the receiver. This input is CMOS compatible,
and is pulled-up on the IC.
Roll-off response of the IF Band-Pass Filter is 5th order, while
the demodulator data filter exhibits a 2nd order response.
The MICRF007 is a standard super-heterodyne receiver with
a narrow IF filter bandwidth of 700kHz. It is less susceptible to
interfering RF signals. The MICRF007 RF center frequency is
controlled by an integrated PLL/VCO frequency synthesizer,
which is locked to the reference oscillator frequency, typically
set by a crystal. A tight tolerance transmitter such as SAW or
crystal-based transmitters must be used for the system.
The MICRF007 has a fully integrated base-band demodulator
filter. The filter has a fixed 2.5kHz bandwidth and exhibits a
2nd order response. This filter limits the receiver raw data
rate to 3.2Kbps NRZ.
M9999-021705
Step 1: Selecting Reference Oscillator
All timing and tuning operations on the MICRF007 are derived from the internal Colpitts reference oscillator. Timing
and tuning is controlled through the REFOSC pin in one of
two ways:
1. Connect a crystal.
2. Drive this pin with an external timing signal.
The specific reference frequency required is related to the
system transmit frequency.
Crystal Selection
Care should be taken to ensure low ESR crystals are selected. “Application Hint 35” provides additional information
and recommended sources for crystals.
When a crystal is used, the minimum voltage is 300mVPP. If
using an externally applied signal, it should be AC-coupled
and limited to the operating range of 0.1VPP to 1.5VPP.
Selecting Reference Oscillator Frequency fT
As with any super-heterodyne receiver, the difference between
the internal local oscillator (LO) frequency fLO and
the incoming transmit frequency fTX should equal the IF
center frequency. Equation 1 may be used to compute the
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February 17, 2005
MICRF007
Micrel
Step 3: Selecting CAGC Capacitor
The signal path has automatic gain control (AGC) to increase
input dynamic range. The attack time constant of the AGC is
set externally by the value of the CAGC capacitor connected
to the CAGC pin of the device. 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
of at least 0.47µF are recommended.
The AGC control voltage is carefully managed on-chip to allow duty-cycle operation of the MICRF007. When the device
is placed into shutdown mode (SHUT pin is pulled high), the
AGC capacitor floats to retain the voltage. When operation
is resumed, only the voltage droop due to capacitor leakage
must be replenished. A relatively low-leakage capacitor is
recommended when the devices are used in duty-cycled
operation.
To further enhance duty-cycled operation, the AGC push
and pull currents are boosted for approximately 10ms immediately after the device is taken out of shutdown. This
compensates for AGC capacitor voltage droop and reduces
the time to restore the correct AGC voltage. The current is
boosted by a factor of 45.
Selecting CAGC Capacitor in Continuous Mode
A CAGC capacitor in the range of 0.47µF to 4.7µF is typically
recommended. Caution! If the capacitor is too large, the
AGC may react too slowly to incoming signals. AGC settling time from a completely discharged (zero-volt) state
is given approximately by this equation:
∆t = 1.333 × CAGC –0.44
(5)
where:
CAGC is in µF, and ∆t is in seconds.
Selecting CAGC Capacitor in Duty-Cycle Mode
Voltage droop across the CAGC capacitor during shutdown
should be replenished as quickly as possible after the IC is
enabled. As mentioned above, the MICRF007 boosts the
push-pull current by a factor of 45 immediately after start-up.
This fixed time period is based on the reference oscillator
frequency fT. The time is 10.9ms for fT = 6.00MHz, and varies
inversely with fT. The value of CAGC capacitor and the duration
of the shutdown time period should be selected such that the
droop can be replenished within this 10ms period.
Polarity of the droop is unknown, meaning the AGC voltage
could droop up or down. The worst-case from a recovery
standpoint is downward droop, since the AGC pull-up current
is 1/10th magnitude of the pull-down current. The downward
droop is replenished according to the Equation 6:
appropriate fLO for a given fTX:
f
�
�
fLO = fTX± �1.18 TX �
(1)
�
433.92 �
Frequencies 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.” High-side mixing results in an
image frequency above the frequency of interest and lowside mixing results in a frequency below. 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 reference oscillator frequency
fT:
fT =
fLO
(2)
64.5
Frequency fT is in MHz. Connect a crystal of frequency fT to
REFOSC on the MICRF007. Four-decimal-place accuracy
on the frequency is generally adequate. The following table
identifies fT for some common transmit frequencies.
Transmit
Reference
Frequency fTX
Oscillator Frequency fT
315MHz
4.8970MHz
390MHz
6.0630MHz
418MHz
6.4983MHz
433.92MHz
6.7458MHz
Table 2. Recommended Reference Oscillator Values
for Typical Transmit Frequencies (high-side mixing)
Step 2: Selecting CTH Capacitor
Extraction of the DC value of the demodulated signal for
purposes of logic-level data slicing is accomplished using the
external threshold capacitor CTH and the on-chip switched
capacitor “resistor” RSC, shown in the block diagram.
Slicing level time constant values vary somewhat with decoder type, data pattern, and data rate, but typically values
range from 5ms to 50ms.This issue is covered in more detail
in “Application Note 22.” Optimization of the value of CTH is
required to maximize range.
τ of 5x the bit-rate is recommended. The effective resistance
of RSC is listed in the electrical characteristics table as 110kΩ
at 433.92MHz, This value scales inversely with frequency.
Source impedance of the CTH pin at other frequencies is
given by equation (3), where fT is in MHz:
RSC = 110kΩ
6.7458
fT
(3)
Since slicing level time constant τ has been established
as 5 times bit rate, capacitor CTH may be computed using
equation (4),
CTH=
CAGC=
(6)
where:
I = AGC pull-up current for the initial 10ms (67.5µA)
CAGC = AGC capacitor value
∆t = droop recovery time

RSC
(4)
A standard ±20% X7R ceramic capacitor is generally sufficient. Refer to “Application Hint 42” for CTH and CAGC selection examples.
February 17, 2005
It
V
7
M9999-021705
MICRF007
Micrel
∆V = droop voltage
For example, if user desires ∆t = 10ms and chooses a 4.7µF
CAGC, then the allowable droop is about 144mV. Using the
same equation with 200nA, the worst case pin leakage, and
assuming 1µA of capacitor leakage in the same direction,
the maximum allowable ∆t (shutdown time) is about 0.56s
for droop recovery in 10ms.
The ratio of decay-to-attack time-constant is fixed at 1:10
(that is, the attack time constant is 10 times of the delay time
constant). Generally, the design value of 1:10 is adequate for
the vast majority of applications. If adjustment is required,
adding a resistor in parallel of the CAGC capacitor may vary
the ratio. The value of the resistor must be determined on a
case by case basis.
Additional Applications Information
In addition to the basic operation of the MICRF007, the following enhancements can be made. In particular, it is strongly
recommended that the antenna impedance is matched to
the input of the IC.
Antenna Impedance Matching
As shown in Figure 2 and Table 3, the antenna pin input
impedance is frequency dependent.
The ANT pin can be matched to 50Ω with a high pass circuit
as shown in Figure 3. That is, a shunt inductor from the
antenna input to ground and a capacitor in series from the
antenna input to the ANT pin.
j100
j25
�
50
0
–j25
Fr eq u en c y
(MHz)
ZIN( Ω )
Z11
S11
CSERIES (pF)
300
12– j16 6
0.803– j0.52 9
1.5
62
305
12– j16 5
0.800– j0.53 0
1.4
62
310
12 – j16 3
0.796– j0.53 6
1.6
56
315
13 – j16 2
0.791– j0.53 6
1.5
56
320
12 – j16 0
0.789– j0.54 3
1.4
56
325
12 – j15 7
0.782– j0.55 0
1.7
51
330
12 - j15 5
0.778– j0.55 6
1.5
51
335
12 – j15 2
0.770– j0.56 4
1.4
51
340
11 - j15 0
0.767– j0.57 2
1.6
47
345
11 – j14 8
0.762– j0.57 8
1.5
47
350
11 – j14 5
0.753– j0.58 6
1.4
47
355
11 – j14 3
0.748– j0.59 2
1.6
43
360
11 – j14 1
0.742– j0.59 7
1.5
43
365
11 – j13 9
0.735– j0.60 3
1.4
43
370
10 – j13 7
0.732– j0.61
1.3
43
375
10 – j13 5
0.725– j0.61 9
1.6
39
380
10 – j13 3
0.718– j0.62 5
1.4
39
LSHUNT (nH)
385
10 – j13 1
0.711– j0.63 1
1.3
39
390
10 – j13 0
0.707– j0.63 4
1.2
39
395
10 – j12 8
0.700– j0.64 1
1.5
36
400
10 – j12 6
0.692– j0.64 7
1.4
36
405
10 – j12 4
0.684– j0.65 3
1.2
36
410
10 – j12 2
0.675– j0.66 0
1.5
33
415
10 – j12 0
0.667– j0.66 7
1.4
33
420
10 – j11 8
0.658– j0.67 3
1.3
33
425
10 – j11 7
0.653– j0.67 7
1.6
30
430
10 – j11 5
0.643– j0.68 4
1.5
30
435
10 – j11 4
0.638– j0.68 7
1.4
30
440
8 – j11 2
0.635– j0.70 4
1.2
30
Table 4. Input Impedance vs. Frequency
–j100
Figure 2. Impedance Looking into Antenna Pin
CSERIES
ANT Pin
LSHUNT
Figure 3. Antenna Impedance Matching Network
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February 17, 2005
MICRF007
Micrel
I/O Pin Interface Circuitry
Inductor values may be different from Table 4, depending
on PCB material, PCB thickness, ground configuration, and
how long the traces are in the layout. Values shown were
charac-terized for a 0.031 inch thickness, FR4 board, solid
ground plane on bottom layer, and very short traces. Murata
and Coilcraft wire-wound 0603 or 0805 surface mount inductors were tested, however, any wire-wound inductor with high
SRF (self-resonance frequency) should do the job.
Shutdown Function
Duty-cycled operation of the MICRF007 (often referred to
as polling) is achieved by turning the MICRF007 on and off
via the SHUT pin. The shutdown function is controlled by a
logic state applied to the SHUT pin. When VSHUT is high, the
device goes into low-power standby mode. This pin is pulled
high internally, it must be externally pulled low to enable the
receiver. It is recommended to connect this pin through a
100kΩ resistor to ground
Power Supply Bypass Capacitors
Power supply bypass capacitor(s) connected to VDD should
have the shortest possible lead lengths to VSS.
Increasing Selectivity with Optional Band-Pass Filter
For applications located in high ambient noise environments,
a fixed value band-pass network may be connected between
the ANT pin and VSS to provide additional receiver selectivity
and input overload protection. A minimum input configuration is included in Figure 10. It provides some filtering and
necessary overload protection.
Data Squelching
During quiet periods (no signal), the data output (DO pin)
transitions randomly with noise. Most decoders can discriminate between this random noise and actual data. But for some
system, it does present a problem. There are three possible
approaches to reduce this output noise:
Interface circuitry for the various I/O pins of the MICRF007
are diagrammed in Figures 4 through 9. The ESD protection
diodes at all input and output pins are not shown.
ANT Pin
Active
Load
50
Active
Bias
6k
Figure 4. ANT Pin
The ANT pin is internally AC-coupled via a 3pF capacitor to
an RF N-Channel MOSFET, as shown in Figure 4. Im-pedance on this pin to VSS is quite high at low frequencies, and
decreases as frequency increases. In the UHF fre-quency
range, the device input can be modeled as 6.3k. in parallel
with 2pF (pin capacitance) to VSS.
CTH Pin
VDD
1.5A
67.5A
Comparator
CAGC
Timout
Figure 5. CTH Pin
15A
675A
Figure 5 illustrates the CTH-pin interface circuit. The CTH
pin is driven from a P-Channel
MOSFET source-follower
VSS
with approximately 10µA of bias. 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 110kΩ. The DC potential at the CTH pin is
approximately 1.6V
CAGC Pin
Figure 6 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 1.5µA, while
the decay current is a 10 times scaling of this, approximately
15µA. Signal gain of the RF/IF strip inside the IC diminishes
as the voltage on CAGC decreases. By simply adding a
capacitor to CAGC pin, the attack/decay time constant ratio
is fixed at 10:1. Modification of the attack/decay ratio is possible by adding resistance from the CAGC pin to either VDD
or VSS, as desired.
Both the push and pull current sources are disabled during
shutdown, which maintains 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 45 times for approximately 10ms after release
of the SHUT pin. This allows rapid recovery of any voltage
drop on CAGC while in shutdown.
1. Analog squelch to raise the demodulator threshold
2. Digital squelch to disable the output when data is not
present
3. Output filter to filter the (high frequency) noise glitches
on the data output pin.
The simplest solution is to add analog squelch by introducing a small offset, or squelch voltage, on the CTH pin so that
noise does not trigger the internal comparator. Usually 20mV
to 30mV is sufficient, and may be achieved by connecting
a several-meg-ohm resistor from the CTH pin to either VSS
or VDD, depending on the desired offset polarity. Since
MICRF007’s receiver AGC noise at the internal comparator
input is always the same (set by the AGC), the squelch offset
requirement does not change as the local noise strength
changes from installation to installation. Introducing squelch
will reduce sensitivity and also reduce range. Only introduce
an amount of offset sufficient to quiet the output. Typical
squelch resistor values range from 10MΩ to 6.8MΩ for low
to high squelch strength.
February 17, 2005
3pF
9
M9999-021705
MICRF007
Micrel
REFOSC Pin
VDD
1.5A
VDDBB
Active
Bias
67.5A
200k
REFOSC
Comparator
30pF
CAGC
250
30pF
30µA
VSSBB
Timout
15A
675A
VSSBB
Figure 8. REFOSC Pin
The reference oscillator (REFOSC) input circuit is shown in
Figure 8. Input impedance is high (290kΩ). This is a Colpitts
oscillator with internal 30pF capacitors. This input is intended
to work with standard crystal connected from this pin to the
VSS pin. The nominal DC bias voltage on this pin is 1.4V.
SHUT Pin
VSS
Figure 6. CAGC Pin
DO Pin
The output stage for the digital output (DO) in Figure 7.
The output is a 20µA push and 18µA pull switched-current
stage. This output stage is capable of driving CMOS loads.
An external buffer-driver is recommended for driving high
capacitance loads.
VDDBB
Q1
VDD
Q2
to Internal
Circuits
VSSBB
SHUT
20µA
Comparator
Q3
VSSBB
DO
Figure 9. SHUT Pin
Control input circuitry is shown in Figure 9. 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”
pull-up to VDD. Typical pull-up current is 5µA.
18µA
VSS
Figure 7. DO Pin
M9999-021705
10
February 17, 2005
MICRF007
Micrel
Application Example
Operation in this example is at 315MHz, and may be customized by selection of the appropriate frequency reference
(Y1), and adjustment of the antenna length. Changes from
the 1Kbps data rate may require a change in the value of R1.
A bill of materials accompanies the schematic.
315MHz Receiver/Decoder Application
Figure 10 illustrates a typical application for the MICRF007
UHF Receiver IC. This receiver operates continuously (not
duty cycled) in fixed-mode, and features 6-bit address decoding and two output code bits.
+5V
Supply Input
1/4 monopole
antenna (23.1cm)
6-bit
address
U1 MICRF007
VSS REFOSC
C4
1.8pF
L1
56nH
C1
C5
4.7µF 100µF
C6
100pF
C2
39nF
ANT
CAGC
VDD
SHUT
CTH
DO
Y1
4.8970MHz
C3
2.2µF
R3
100k
U2 HT-12D
A0
A1
A2
A3
A4
VDD
VT
OSC1
OSC2
DIN
A5
A6
D11
D10
A7
D9
VSS
D8
R2
1k
R1
68k
Code Bit 0
Code Bit 1
RF
Baseband
(Analog) (Digital)
Ground Ground
Figure 10. 315MHz, 1Kbps On-Off Keyed Receiver with Decoder
Bill of Materials
Item
Part Number
Manufacturer
Description
C1
GRM21BF51A475ZA01L
Murata(7)
4.7µF Y5V
Qty.
C2
VJ0603Y393KXXA
Vishay(1)
39nF
1
C3
GRM188R61A225XE348
Murata(7)
2.2µF X5R
1
C4
GRM1885C1H1R8CZ01B
Murata(7)
1.8pF COG ceramic capacitor
1
C5
GRM188R71E104KA01B
Murata(7)
100nF capacitor
1
C6
GRM1885C1H101JA01B
Murata(7)
100pF capacitor
1
D1
SSF-LX100LID
Lumex(2)
red LED
1
L1
0603CS-56NX-B
Coilcraft(6)
56mH wire wound, Q=38
1
R1
CRCW06036812F
Vishay(1)
68k; 1/4W; 5%
1
R2
CRCW06031001F
Vishay(1)
1k; 1/4W; 5%
1
R3
CRCW06031003F
Vishay(1)
100k
1
U1
MICRF007BM
Micrel(3)
UHF Reciever
1
U2
HT-12D
Holtek(4)
Logic decoder
1
Y1
AB-4.8970MHZ-20-D
Abracon(5)
4.8970MHz crystal
1
1
Notes:
1. Vishay, tel. (203) 268-6261
2. Lumex, tel. (800) 278-5666
3. Micrel Inc., tel (408) 944-0800
4. Holteck, tel (408) 894-9046
5. Abracon, tel. (949) 448-7070
6. Coilcraft, tel. (510) 814-8954
7. Murata, tel (408) 397-1284
February 17, 2005
11
M9999-021705
MICRF007
Micrel
PCB Layout Information
The MICRF007 evaluation board was designed and characterized using double sided 0.031 inch thick FR4 material with
1 ounce copper clad. If another type of printed circuit board
material is substituted, impedance matching and characterization data may not be as stated in this document.
PCB Silk Screen
PCB Component Side Layout
PCB Solder Side Layout
1
2
+5V
ANT1
50½ Ant
J2
(np) SMA
1
C3
2.0pF
50V
2
+5V
L1
(np)
U1 MICRF007BM
L2
27nH
3
R1
(np)
4
VSS REFOSC
ANT
CAGC
VDD
SHUT
CTH
DO
8
C2
(np)
C1
(np) CAGC
REFOSC
GND
J1
(np) CON2
7
SH
6
5
C4
CAGC
Y1
6.7458MHz
DO
+5V
+5V
GND
DO
SH
1
2
3
4
5
L3
(np) ZCB-0603
+5V
C5
0.1µF
16V
C6
(CTH)
R2
(np)
C7
(np)
R3
100k½
DO
SH
Note:
CTH and CAGC should be
optimized according to data
rate and data format.
(np) = component not placed.
J3
CON5
Figure 11. 433.92MHz Schematic QR007-50-433
M9999-021705
12
February 17, 2005
MICRF007
Micrel
Package Information
0.026 (0.65)
MAX)
PIN 1
0.157 (3.99)
0.150 (3.81)
DIMENSIONS:
INCHES (MM)
0.020 (0.51)
0.013 (0.33)
0.050 (1.27)
TYP
0.064 (1.63)
0.045 (1.14)
45
0.0098 (0.249)
0.0040 (0.102)
0.197 (5.0)
0.189 (4.8)
0–8
0.010 (0.25)
0.007 (0.18)
0.050 (1.27)
0.016 (0.40)
SEATING
PLANE
0.244 (6.20)
0.228 (5.79)
8-Lead SOIC (M)
MICREL, INC.
2180 FORTUNE DRIVE
SAN JOSE, CA 95131
USA
TEL + 1 (408) 944-0800 FAX + 1 (408) 474-1000 WEB http://www.micrel.com
The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use.
Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not�
reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into
the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser’s
use or sale of Micrel Products for use in life support appliances, devices or systems is at Purchaser’s own risk and Purchaser agrees to fully indemnify
Micrel for any damages resulting from such use or sale.
© 2004 Micrel, Incorporated.
February 17, 2005
13
M9999-021705