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74HCT297 PDF даташит

Спецификация 74HCT297 изготовлена ​​​​«Philips» и имеет функцию, называемую «Digital phase-locked-loop filter».

Детали детали

Номер произв 74HCT297
Описание Digital phase-locked-loop filter
Производители Philips
логотип Philips логотип 

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74HCT297 Даташит, Описание, Даташиты
INTEGRATED CIRCUITS
DATA SHEET
For a complete data sheet, please also download:
The IC06 74HC/HCT/HCU/HCMOS Logic Family Specifications
The IC06 74HC/HCT/HCU/HCMOS Logic Package Information
The IC06 74HC/HCT/HCU/HCMOS Logic Package Outlines
74HC/HCT297
Digital phase-locked-loop filter
Product specification
File under Integrated Circuits, IC06
September 1993









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74HCT297 Даташит, Описание, Даташиты
Philips Semiconductors
Digital phase-locked-loop filter
Product specification
74HC/HCT297
FEATURES
Digital design avoids analog compensation errors
Easily cascadable for higher order loops
Useful frequency range:
– DC to 55 MHz typical (K-clock)
– DC to 35 MHz typical (I/D-clock)
Dynamically variable bandwidth
Very narrow bandwidth attainable
Power-on reset
Output capability: standard/bus driver
ICC category: MSI
GENERAL DESCRIPTION
The 74HC/HCT297 are high-speed Si-gate CMOS devices
and are pin compatible with low power Schottky TTL
(LSTTL). They are specified in compliance with JEDEC
standard no. 7A.
The 74HC/HCT297 are designed to provide a simple,
cost-effective solution to high-accuracy, digital,
phase-locked-loop applications. These devices contain all
the necessary circuits, with the exception of the
divide-by-n counter, to build first order
phase-locked-loops.
Both EXCLUSIVE-OR (XORPD) and edge-controlled
(ECPD) phase detectors are provided for maximum
flexibility. The input signals for the EXCLUSIVE-OR phase
detector must have a 50% duty factor to obtain the
maximum lock-range.
Proper partitioning of the loop function, with many of the
building blocks external to the package, makes it easy for
the designer to incorporate ripple cancellation (see Fig.7)
or to cascade to higher order phase-locked-loops.
The length of the up/down K-counter is digitally
programmable according to the K-counter function table.
With, A, B, C and D all LOW, the K-counter is disabled.
With A HIGH and B, C and D LOW, the K-counter is only
three stages long, which widens the bandwidth or capture
range and shortens the lock time of the loop. When A, B,
C and D are all programmed HIGH, the K-counter
becomes seventeen stages long, which narrows the
bandwidth or capture range and lengthens the lock time.
Real-time control of loop bandwidth by manipulating the A
to D inputs can maximize the overall performance of the
digital phase-locked loop.
The “297” can perform the classic first-order
phase-locked-loop function without using analog
components. The accuracy of the digital
phase-locked-loop (DPLL) is not affected by VCC and
temperature variations but depends solely on accuracies
of the K-clock, I/D-clock and loop propagation delays.
The phase detector generates an error signal waveform
that, at zero phase error, is a 50% duty factor square wave.
At the limits of linear operation, the phase detector output
will be either HIGH or LOW all of the time depending on the
direction of the phase error (φIN − φOUT). Within these limits
the phase detector output varies linearly with the input
phase error according to the gain kd, which is expressed in
terms of phase detector output per cycle or phase error.
The phase detector output can be defined to vary between
± 1 according to the relation:
phase detector output = %--------H----I--G----H--1---˙0--˙--0--%-------L---O-----W---- .
The output of the phase detector will be kdφe, where the
phase error φe = φIN − φOUT.
EXCLUSIVE-OR phase detectors (XORPD) and
edge-controlled phase detectors (ECPD) are commonly
used digital types. The ECPD is more complex than the
XORPD logic function but can be described generally as a
circuit that changes states on one of the transitions of its
inputs. The gain (kd) for an XORPD is 4 because its output
remains HIGH (XORPDOUT = 1) for a phase error of 1/4
cycle.
Similarly, kd for the ECPD is 2 since its output remains
HIGH for a phase error of 1/2 cycle. The type of phase
detector will determine the zero-phase-error point, i.e., the
phase separation of the phase detector inputs for a
φe defined to be zero. For the basic DPLL system of
Fig.6 φe = 0 when the phase detector output is a square
wave.
The XORPD inputs are 1/4 cycle out-of-phase for zero
phase error. For the ECPD, φe = 0 when the inputs are 1/2
cycle out-of-phase.
The phase detector output controls the up/down input to
the K-counter. The counter is clocked by input frequency
Mfc, which is a multiple M of the loop centre frequency fc.
When the K-counter recycles up, it generates a carry
pulse. Recycling while counting down generates a borrow
pulse. If the carry and the borrow outputs are conceptually
combined into one output that is positive for a carry and
negative for a borrow, and if the K-counter is considered as
a frequency divider with the ratio Mfc/K, the output of the
K-counter will equal the input frequency multiplied by the
division ratio. Thus the output from the K-counter is
(kdφeMfc) / K.
September 1993
2









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74HCT297 Даташит, Описание, Даташиты
Philips Semiconductors
Digital phase-locked-loop filter
Product specification
74HC/HCT297
The carry and borrow pulses go to the
increment/decrement (I/D) circuit which, in the absence of
any carry or borrow pulses has an output that is 1/2 of the
input clock (I/DCP). The input clock is just a multiple, 2N, of
the loop centre frequency. In response to a carry or borrow
pulse, the I/D circuit will either add or delete a pulse at
I/DOUT. Thus the output of the I/D circuit will be
Nfc + (kdeMfc)/2K.
The output of the N-counter (or the output of the
phase-locked-loop) is thus: fo = fc + (kdφeMfc)/2KN.
If this result is compared to the equation for a first-order
analog phase-locked-loop, the digital equivalent of the
gain of the VCO is just Mfc/2KN or fc/K for M = 2N.
Thus the simple first-order phase-locked-loop with an
adjustable K-counter is the equivalent of an analog
phase-locked-loop with a programmable VCO gain.
QUICK REFERENCE DATA
GND = 0 V; Tamb = 25 °C; tr = tf = 6 ns
SYMBOL PARAMETER
CONDITIONS
tPHL/ tPLH
fmax
CI
CPD
propagation delay
I/DCP to I/DOUT
φA1, φB to XORPDOUT
φB, φA2 to ECPDOUT
maximum clock frequency
KCP
I/DCP
input capacitance
power dissipation capacitance per package
CL = 15 pF; VCC = 5 V
notes 1 and 2
Notes
1. CPD is used to determine the dynamic power dissipation (PD in µW):
PD = CPD × VCC2 × fi + ∑ (CL × VCC2 × fo) where:
fi = input frequency in MHz
fo = output frequency in MHz
(CL × VCC2 × fo) = sum of outputs
CL = output load capacitance in pF
VCC = supply voltage in V
2. For HC the condition is VI = GND to VCC
For HCT the condition is VI = GND to VCC 1.5 V
TYPICAL
HC HCT
15 18
13 13
19 19
63 68
41 40
3.5 3.5
18 19
UNIT
ns
ns
ns
MHz
MHz
pF
pF
ORDERING INFORMATION
See “74HC/HCT/HCU/HCMOS Logic Package Information”.
September 1993
3










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