MICRF002BN 데이터 시트보기 (PDF) - Micrel
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MICRF002BN Datasheet PDF : 13 Pages
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MICRF002
I/O Pin Interface Circuitry
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3. CAGC Pin
Micrel
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.
1. ANT Pin
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.
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.
Figure 1 ANT Pin
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.
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
4. DO and WAKEB Output Pins
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.
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.
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
11
MICRF002
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