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SP8858IGHCAR Datasheet(PDF) 10 Page - Zarlink Semiconductor Inc

Part # SP8858IGHCAR
Description  1쨌5GHz Professional Synthesiser
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Manufacturer  ZARLINK [Zarlink Semiconductor Inc]
Direct Link  http://www.zarlink.com
Logo ZARLINK - Zarlink Semiconductor Inc

SP8858IGHCAR Datasheet(HTML) 10 Page - Zarlink Semiconductor Inc

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10
SP8858
signal at the phase detector input. The multiplied reference
signal phase noise can set the limit on the achievable close-
in phase noise. It is important then that the reference signal is
a low phase noise source with good long term stability.
The residual noise of the reference divider is also important
because, at some offsets from the carrier, the dividers limit the
phase noise reduction that is achievable when the reference
signal is divided down to FREF. More detailed advice on phase
noise optimisation is given in Ref. 1.
Charge Pump Output
CP OUTPUT (pin 26) and CP REF (pin 5) are connected
directly to the inverting and non-inverting input of the loop filter
amplifier respectively as shown in Fig. 12. The CP OUTPUT
pin will source/sink a current to/from the inverting input equal
in magnitude to, or a multiple of, a current reference flowing
into RPD (pin 24). The multiplication factor is programmed by
two bits (G1 and G2) in the F1 or F2 word (see Data Entry and
Control section).
The CP OUTPUT has two stable states. The ON state
sourcing or sinking a fixed current and an OFF state in which
no current will flow from or into the CP output pin. The
proportion of time the charge pump is ON depends on the
frequency/phase relationship between the reference signal
(divided by R) and the VCO signal (divided by N) at the phase
detector input:
q
The digital phase detector is sensitive to a frequency
difference between the two input signals and will source or
sink a constant current for frequency differences.
q
When phase-lock is acquired the charge pump current ON/
OFF ratio is in direct proportion to the phase difference
between the two signals at the phase detector input.
Starting from the state ‘charge pump OFF’ the edge of the
leading signal triggers the charge pump into the ON state.
The edge of the lagging signal briefly triggers a current at
the output which is opposite in sign and equal in magnitude
to the current already present before the charge pump
returns to the OFF state. When the phase difference
reaches zero the input signals simultaneously trigger brief
source and sink current pulses which cancel at the output
so that zero phase error gives zero output and the deadband
is eliminated. The pulse widths are determined by the time
taken to reset the internal flip-flops.
In practice, when the loop is phase locked and the charge
pump is predominately in the OFF state there are two
imperfections to consider:
q
The loop filter capacitors discharge during the period of the
reference signal.
q
A small current leaks into CP OUTPUT in the OFF state at
high charge-pump current settings.
A small correction is therefore required each cycle. The
resulting disturbance is attenuated by the loop but any residual
ripple on the VCO control frequency modulates the VCO
causing the characteristic reference sidebands. The magnitude
of the sidebands that can be tolerated depends entirely on the
application and can be reduced by setting a loop bandwidth
very much less than the phase detector comparison frequency
(FREF) or by reducing the charge-pump current (the leakage
current is negligible for low charge-pump currents).
The charge-pump can be set to source or sink a current for
any given phase difference and the SENSE bit in the F1 (or
F2) programme word is used to set the appropriate sign for the
application. The SENSE bit should be set to 1 for a VCO with
a positive frequency versus control voltage characteristic to
ensure phase lock.
The actual bias voltage at the CP REF pin varies with the
magnitude of the reference current and CP OUT is held at the
same voltage by the operational amplifier. A low offset voltage
amplifier should be chosen to maintain the match between the
reference current into RPD (pin 24) and the actual output
current.
The simplest method of setting the reference current is to
connect a resistor between RPD and the supply. The voltage
at pin 24 is approximately 1·5V but this varies slightly with the
magnitude of the current and a simple calculation of Ipin 24 =
(VCC21·5)/RPD (see Description, Data Entry and Control) is
approximate. The voltage at pin 24 will also vary with
temperature and the impact of the phase detector gain
variations on performance should be assessed in each
individual application. If it is considered important to improve
the accuracy of the phase detector gain then the use of a
constant current source may be more appropriate.
Miscellaneous I/Os
The SP8858 includes simple lock-detect circuit. The output
signals from the Reference and RF dividers are used to drive
an EXOR type phase detector. The output of this type of
detector is logic high if the inputs are at the same voltage level
and low if the inputs are polarised. The EXOR gate drives a
buffer stage with the output collector loaded with a single
50k
Ω on-chip resistor and a capacitor connected externally at
pin 28 (CD). The RC serves to integrate the output pulse train
from the phase detector. The capacitor voltage must reach a
fixed threshold to enable a constant current sink into pin 27.
The inputs POWER DOWN and F1/F2 can either be fixed
at the required logic level or controlled by some peripheral
circuit. See Table 1 and Fig. 12.
As with any RF design work care must be taken with the
power supply layout to and the returns from the IC and the
physical position of the PLL on the PCB in relation to potential
interference sources. The VCC supply inputs should be
connected to a well regulated 5V power supply and locally
decoupled; noise on the supply can influence the noise power
spectrum of the output signal.
The programming inputs DATA, CLOCK and ENABLE are
compatible with standard CMOS and TTL logic and are
subject to the timing restrictions shown in Fig. 4.
Loop Filter Design
The linear model of the PLL, as shown in Fig.7, includes an
external loop-filter F(s). A filter is required that will:
q
Add a zero to the open-loop transfer function thus allowing
the designer to manipulate the closed-loop root locations
through the appropriate choice of filter components. Without
the filter (F(s) = 1) the closed loop is first order with the root
locus travelling along the negative real axis with increasing
DC gain. In this situation the designer has very little control
over the
fo(s)/fi(s) transfer characteristic because the
selection of the gain factor KPD KVCO/N may, in practice, be
limited.
q
Introduce a second pole at the origin in order to increase
the type number of the loop to type II. This is required to
ensure that the steady state error signal tends to zero for
a ramp in phase.
In addition, a suitable interface is required to provide the
transimpedance function from the charge-pump output to the
VCO thus converting the output signal, in the form of current
pulses, to the voltage signal required at the VCO input.
The required transfer function is therefore F(s) = (s+a)/s
(zero at 2a) and the loop filter is implemented using the circuit
and formula shown in Fig. 10a. The closed-loop transfer
function becomes:
fo(s)/fi(s) = (st111)KVCOKPD/(s21st1K/C11K/C1)
where
K = KVCOKPD/N
t1 = C1R1


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