EV-ADF4196SD1Z 查看數據表(PDF) - Analog Devices
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EV-ADF4196SD1Z Datasheet PDF : 28 Pages
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Data Sheet
ADF4196
THEORY OF OPERATION
GENERAL DESCRIPTION
RF INPUT STAGE
The ADF4196 is targeted at GSM base station requirements,
specifically to eliminate the need for ping-pong solutions.
It can also be used in pulse Doppler radar applications. The
ADF4196 works on the basis of fast lock, using a wide loop
bandwidth during a frequency change and narrowing the loop
bandwidth when frequency lock is achieved.
Widening the loop bandwidth is achieved by increasing the
charge pump current. To maintain stability with the changing
charge pump current, the ADF4196 includes switches that
change the loop filter component values.
The RF input stage is shown in Figure 21. It is followed by a
two-stage limiting amplifier to generate the CML clock levels
needed for the prescaler. Two prescaler options are available:
4/5 and 8/9. Select the 8/9 prescaler for N divider values that
are greater than 80.
BIAS
GENERATOR
1.6V
AVDD
RFIN+
500Ω
500Ω
The narrow loop bandwidth ensures that phase noise and spur
specifications are met. A differential charge pump and loop filter
topology ensure that the fast lock time benefit obtained from
widening the loop bandwidth is maintained when the loop is
restored to narrow bandwidth mode for normal operation.
RFIN–
AGND
Figure 21. RF Input Stage
REFERENCE INPUT
RF N Divider
The reference input stage is shown in Figure 20. Switch SW1
and Switch SW2 are normally closed, and Switch SW3 is
normally open. During power-down, SW3 is closed, and SW1
and SW2 are opened to ensure that there is no loading of the
REFIN pin. The falling edge of REFIN is the active edge at the
positive edge triggered PFD.
POWER-DOWN
CONTROL
NC 100kΩ
REFIN NC
SW2
SW1
SW3
NO
TO R COUNTER
BUFFER
The RF N divider allows a fractional division ratio in the PLL
feedback path. The integer and fractional parts of the division
are programmed using separate registers, as shown in Figure 22
and described in the INT, FRAC, and MOD Relationship section.
Integer division ratios from 26 to 511 are allowed, and a third-
order Σ-Δ modulator interpolates the fractional value between
the integer steps.
FROM RF
INPUT STAGE
RF N DIVIDER
N COUNTER
N = INT + FRAC/MOD
TO PFD
THIRD-ORDER
FRACTIONAL
INTERPOLATOR
Figure 20. Reference Input Stage
INT
VALUE
MOD
VALUE
FRAC
VALUE
R Counter and Doubler
The 4-bit R counter allows the input reference frequency to
be divided down to produce the reference clock to the PFD.
A toggle flip-flop can be inserted after the R counter to provide
Figure 22. Fractional-N RF Divider
INT, FRAC, and MOD Relationship
an additional divide-by-2. Using this option has the added
The INT, FRAC, and MOD values, programmed through the
advantage of ensuring that the PFD reference clock has a 50/50
serial interface, make it possible to generate RF output frequencies
mark-to-space ratio. This ratio gives the maximum separation
that are spaced by fractions of the PFD reference frequency.
between the fast lock timer clock, which is generated off the
The N divider value, shown inside the brackets of the following
falling edge of the PFD reference, and the rising edge, which is
the active edge in the PFD. It is recommended that this toggle
equation for the RF VCO frequency (RFOUT), is composed of an
integer part (INT) and a fractional part (FRAC/MOD).
flip-flop be enabled for all even R divide values that are greater
than 2. The flip-flop must be enabled if dividing down a REFIN
frequency that is greater than 120 MHz.
An optional doubler before the 4-bit R counter can be used for
low REFIN frequencies, up to 20 MHz. With these programmable
options, reference division ratios from 0.5 to 30 between REFIN
and the PFD are possible.
RFOUT = fPFD × [INT + (FRAC/MOD)]
(1)
where:
RFOUT is the output frequency of the external VCO.
fPFD is the PFD reference frequency.
The value of MOD is chosen to give the desired channel step
with the available reference frequency. Then, program the INT
and FRAC words for the desired RF output frequency. See the
Worked Example section for more information.
Rev. D | Page 11 of 28
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