AD607 Ver la hoja de datos (PDF) - Analog Devices
Número de pieza
componentes Descripción
Fabricante
AD607 Datasheet PDF : 24 Pages
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VPOS
AD607
2RT
RT
IFOP
BPF
2RT
AD607
are generated at IOUT and QOUT, respectively. The quadra-
ture accuracy of this VFQO is typically –1.2°C at 10.7 MHz. The
PLL uses a sequential-phase detector that comprises low power
emitter-coupled logic and a charge pump (Figure 20).
DMIP
a. Biasing DMIP from Power Supply (Assumes BPF
AC-Coupled Internally)
AD607
RT
IFOP
BPF
DMIP
VMID
RT
CBYPASS
b. Biasing DMIP from VMID (Assumes BPF
AC-Coupled Internally)
Figure 19. Suggested Methods for Biasing Pin DMIP
at VP/2
For IFs < 3 MHz, the on-chip low-pass filters (2 MHz cutoff)
do not attenuate the IF or feedthrough products. Thus, the
maximum input voltage at DMIP must be limited to ± 75 mV
to allow sufficient headroom at the I and Q outputs for not only
the desired baseband signal, but also the unattenuated higher-
order demodulation products. These products can be removed
by an external low-pass filter. In the case of IS54 applications
using a 455 kHz IF and the AD7013 baseband converter, a simple
one-pole RC filter with its corner above the modulation band-
width is sufficient to attenuate undesired outputs.
Phase-Locked Loop
The demodulators are driven by quadrature signals that are
provided by a variable frequency quadrature oscillator (VFQO),
phase-locked to a reference signal applied to Pin FDIN. When
this signal is at the IF, in-phase and quadrature baseband outputs
F
SEQUENTIAL U
PHASE
R
DETECTOR D
REFERENCE CARRIER
(FDIN AFTER LIMITING)
IU~
40A
VF
VARIABLE-
FREQUENCY
QUADRATURE
C OSCILLATOR
ID~
R
40A
I-CLOCK
90؇
Q-CLOCK
(ECL OUTPUTS)
Figure 20. Simplified Schematic of the PLL and
Quadrature VCO
The reference signal may be provided from an external source
in the form of a high level clock, typically a low level signal
(± 400 mV) since there is an input amplifier between FDIN and
the loop’s phase detector. For example, the IF output itself can
be used by connecting DMIP to FDIN, which will then provide
automatic carrier recover for synchronous AM detection and
take advantage of any post-IF filtering. Pin FDIN must be
biased at VP/2; Figure 22 shows suggested methods.
The VFQO operates from 400 kHz to 12 MHz and is controlled
by the voltage between VPOS and FLTR. In normal operation,
a series RC network forming the PLL loop filter is connected
from FLTR to ground. The use of an integral sample-hold
system ensures that the frequency-control voltage on Pin FLTR
remains held during power-down, so reacquisition of the carrier
typically occurs in 16.5 µs.
In practice, the probability of a phase mismatch at power-up is
high, so the worst-case linear settling period to full lock needs
to be considered in making filter choices. This is typically 16.5 µs
at an IF of 10.7 MHz for a ±100 mV signal at DMIP and FDIN.
Table II. AD607 Gain and Manual Gain Control Voltage vs. Power Supply Voltage
Power Supply
Voltage
(V)
GREF
(= VMID)
(V)
Scale Factor
(dB/V)
3.0
1.5
50.00
3.5
1.75
42.86
4.0
2.0
37.50
4.5
2.25
33.33
5.0
2.5
30.00
5.5
2.75
27.27
Maximum gain occurs for gain control voltage = 0 V.
Scale Factor
(mV/dB)
20.00
23.33
26.67
30.00
33.33
36.67
Gain Control
Voltage Input Range
(V)
0.400–2.000
0.467–2.333
0.533–2.667
0.600–3.000
0.667–3.333
0.733–3.667
REV. C
–17–
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