MICRF219AAYQS 데이터 시트보기 (PDF) - Micrel
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MICRF219AAYQS Datasheet PDF : 25 Pages
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Micrel, Inc.
The ability of the chip to track to a signal that
DECREASED in strength is much slower, since only
1.5μA is available to charge CAGC to increase the gain.
When designing a transmitter that communicates with
the MICRF219A, ensure that the power level remains
constant throughout the transmit burst.
The value of CAGC impacts the time to good data
(TTGD), which is defined as the time when signal is first
applied, to when the pulse width at DO is within 10% of
the steady state value. The optimal value of CAGC
depends on the setting of the D4 and D3 bits. A smaller
CAGC value does NOT always result in a shorter TTGD.
This is due to the loop dynamics, the fast discharge
current being 600µA, and the charge current being only
1.5µA. For example, if D4 = D3 = 0, the low pass filter
bandwidth is set to a minimum and CAGC capacitance is
too small, TTGD will be longer than if CAGC capacitance
is properly chosen. This is because when RF signal first
appears, the fast discharge period will reduce VCAGC very
fast, lowering the gain of the mixer and IF amplifier. But
since the low pass filter bandwidth is low, it takes too
long for the AGC comparator to see a reduced level of
the audio signal, so it can not stop the discharge current.
This causes an undershoot in CAGC voltage and a
corresponding overshoot in RSSI voltage. Once CAGC
undershoots, it takes a long time for it to charge back up
because the current available is only 1.5µA.
Table 3 lists the recommended minimum CAGC values
for different D[4:3] settings to insure that the voltage on
CAGC does not undershoot. The recommendation also
takes into account the behavior in auto-polling. If CAGC
is too small, the chip can have a tendency to false wake
up (DO releases even when there is no input signal).
D4
D3 CAGC value
0
0
4.7μF
0
1
2.2μF
1
0
1μF
1
1
1μF
Table 3. Minimum Suggested CAGC Values
Figure 3 illustrates what occurs if CAGC capacitance is
too small for a given D[4:3] setting. Here, D[4:3] = 01,
the capacitance on CAGC pin is 0.47μF, and the RF
input level is stepped from no signal to −100dBm. RSSI
voltage is shown instead of CAGC voltage because
RSSI is a buffered version of CAGC (with an inversion
and amplification). Probing CAGC directly can affect the
loop dynamics through resistive loading from a scope
probe, especially in the state where only 1.5μA is
available, whereas probing RSSI does not. When RF
signal is first applied, RSSI voltage overshoots due to
MICRF219A
the fast discharge current on CAGC, and the loop is too
slow to stop this fast discharge current in time. Since the
voltage on CAGC is too low, the audio signal level is
lower than the slicing threshold (voltage on CTH), and
DO pin is low. Once the fast discharge current stops,
only the small 1.5µA charge current is available in
settling the AGC loop to the correct level, causing the
recovery from CAGC undershoot/RSSI overshoot
condition to be slow. As a result, TTGD is about 9.1ms.
Figure 3. RSSI Overshoot and Slow TTGD (9.1ms)
Figure 4 shows the behavior with a larger capacitor on
CAGC pin (2.2μF), D[4:3] = 01. In this case, VCAGC does
not undershoot (RSSI does not overshoot), and TTGD is
relatively short at 1ms.
Figure 4. Proper TTGD (1ms) with Sufficient CAGC
August 12, 2015
11
Revision 3.0
RadioTech@micrel.com or (408) 944-0800
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