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Claims  |
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What is claimed is:
1. In a frequency synthesizer device having a phase locked loop comprising
voltage controlled oscillator means, reference frequency oscillator means
and phase comparator means for comparing a phase difference between
outputs from the voltage controlled oscillator means and the reference
frequency oscillator means to apply the compared output to the voltage
controlled oscillator means to stabilize the oscillating frequency
thereof, an improvement comprising;
means for generating a series of harmonic waves from the reference signal
from said reference frequency oscillator means, said series of harmonic
waves being applied to said phase comparator means for phase comparing
with the output from said voltage controlled oscillator means,
means for coarsely changing the output frequency of said voltage controlled
oscillator means to a desired frequency,
first gate means coupled with the output of said voltage controlled
oscillator means,
counter means for counting the number of output waves from said voltage
controlled oscillator means through said first gate means,
first latching means coupled with an output of said counter means which
provides the least significant digit of a decimal number of a count by
said counter means,
second gate means connected in a closed loop comprising said voltage
controlled oscillator means and said phase comparator means,
means for providing a gate signal to make said second gate means conductive
at a time when the number from said first latching means is within a
predetermined range,
second latching means coupled with said counter means,
first indicator means for indicating the desired frequency value
correspondingly to the counted number through said second latching means,
and means coupled with the output from said reference frequency oscillator
means for providing a gate pulse to make said first gate means conductive,
latching signals to operate said first and second latching means and a
reset signal to reset said counter means, said gate pulse having a pulse
width predetermined correspondingly to the reference frequency and being
repeatedly generated with a constant period, said latching signals being
provided just after each one of said gate pulses ends, and said reset
signal being generated after said latching signals but before next gate
pulse.
2. The improvement as claimed in claim 1, wherein said coarsely frequency
changing means is provided with a second indicator means for indicating
numbers of the higher orders of the desired frequency value selected
thereby, said first indicator means indicating numbers of the lower orders
of the desired frequency value correspondingly to the counted number
through said second latching means.
3. The improvement as claimed in claim 2, wherein said pulse width of said
gate pulse is determined equal to the period of said reference frequency,
said predetermined range at a time when said gate signal providing means
generates the gate signal being the numbers 9, 0 and 1.
4. The improvement as claimed in claim 3, wherein the reference frequency
is determined 10.sup.n Hz (n is a positive integer), said counter means
comprising a first counter means for decimal numbers of one digit and a
second counter means for counting carry signals from said first counter
means to provide said numbers of the lower orders, and said first
indicator means indicating the counted numbers at said second counter
means.
5. The improvement as claimed in claim 4, wherein said harmonic waves
generating means is a monostable multivibrator circuit.
6. The improvement as claimed in claim 4, wherein said coarsely frequency
changing means is a variable condenser of a type including movable
electrode means, said second indicator means being controlled by the
movement of said movable electrode means.
7. The improvement as claimed in claim 4, wherein said coarsely frequency
changing means is a variable voltage DC source means, the output of said
variable DC source means being applied to said voltage controlled
oscillator to control the oscillating frequency thereof.
8. The improvement as claimed in claim 4, which further comprises digital
analogue converter means for converting the number from said first
latching means into a corresponding analogue signal, said analogue signal
being zero voltage at a time when said number from said first latching
means is within the range of 9, 0 and 1, and means for applying said
analogue signal to said voltage controlled oscillator means as a voltage
control signal.
9. The improvement as claimed in claim 8, wherein said analogue signal
applying means is an adder circuit means which has two input terminals
coupled with the outputs of said phase comparator means and said
digital-analogue converter means, respectively, and an output terminal
connected to said voltage controlled oscillator for frequency control
thereof.
10. The improvement as claimed in claim 9, wherein said coarsely frequency
changing means is a variable voltage DC source means, said adder circuit
means having a further input terminal connected to the output of said
variable voltage DC source means, and said second indicator means being
controlled together with said variable voltage DC source means.
11. A frequency synthesizer device which comprises:
a phase locked loop comprising voltage controlled oscillator means,
reference frequency oscillator means, means for generating a series of
harmonic waves from the reference frequency signal from said reference
frequency oscillator means, mixer means for mixing both outputs of said
voltage controlled oscillator means and said harmonic wave generating
means, IF frequency generating means for generating IF frequency wave
having a frequency of a (a is a positive integer) times of the reference
frequency value, phase-comparator means for phase-comparing the output of
said mixer means with the IF frequency wave to apply the compared output
to said voltage controlled oscillator means to stabilize the oscillating
frequency thereof,
means for coarsely changing the output frequency of said voltage controlled
oscillator means to a desired frequency,
first gate means coupled with the output of said voltage controlled
oscillator means,
counter means for counting the number of output waves from said voltage
controlled oscillator means through said first gate means,
first latching means coupled with an output of said counter means which
provides the least significant digit of a decimal number of a count by
said counter means,
second gate means being connected in a closed loop comprising said voltage
controlled oscillator means, said mixer means and said phase comparator
means,
means for providing a gate signal to make said second gate means conductive
at a time when the number from said first latching means is within a
predetermined range,
second latching means coupled with said counter means,
first indicator means for indicating the desired frequency value
correspondingly to the counted number through said second latching means,
and means coupled with the output from said reference frequency oscillator
means for providing a gate pulse to make said first gate means conductive,
latching signals to operate said first and second latching means and a
reset signal to reset said counter means, said gate pulse having a pulse
width predetermined correspondingly to the reference frequency and being
repeatedly generated with a constant period, said latching signals being
provided just after each one of said gate pulses ends, and said reset
signal being generated after said latching signals but before next gate
pulse.
12. The synthesizer as claimed in claim 11, wherein said coarsely frequency
changing means is provided with a second indicator means for indicating
numbers of the higher orders of the desired frequency value selected
thereby, said first indicator means indicating numbers of the lower orders
of the desired frequency value correspondingly to the counted number
through said second latching means.
13. The synthesizer as claimed in claim 12, wherein said pulse width of
said gate pulse is determined equal to the period of said reference
frequency, said predetermined range at a time when said gate signal
providing means generates the gate signal being the number 9, 0 and 1.
14. The synthesizer as claimed in claim 13, wherein the reference frequency
is determined 10.sup.n Hz (n is a positive integer), said counter means
comprising a first counter means for decimal numbers of one digit and a
second counter means for counting carry signals from said first counter
means to provide said numbers of the lower orders, and said first
indicator means indicating the counted numbers at said second counter
means.
15. The synthesizer as claimed in claim 14, wherein said harmonic waves
generating means is a monostable multivibrator circuit.
16. The synthesizer as claimed in claim 14, wherein said coarsely frequency
changing means is a variable condenser of a type including movable
electrode means, said second indicator means being controlled by the
movement of said movable electrode means.
17. The synthesizer as claimed in claim 14, wherein said coarsely frequency
changing means is a variable voltage DC source means, the output of said
variable DC source means being applied to said voltage controlled
oscillator to control the oscillating frequency thereof.
18. The synthesizer as claimed in claim 14, which further comprises digital
analogue converter means for converting the number from said first
latching means into a corresponding analogue signal, said analogue signal
being zero voltage at a time when said number from said first latching
means is within the range of 9, 0 and 1, and means for applying said
analogue signal to said voltage controlled oscillator means as a voltage
control signal.
19. The synthesizer as claimed in claim 18, wherein said analogue signal
applying means is an adder circuit means which has two input terminals
coupled with the outputs of said phase comparator means and said
digital-analogue converter means, respectively, and an output terminal
connected to said voltage controlled oscillator for frequency control
thereof.
20. The synthesizer as claimed in claim 19, wherein said coarsely frequency
changing means is a variable voltage DC source means, said adder circuit
means having a further input terminal connected to the output of said
variable voltage DC source means, and said second indicator means being
controlled together with said variable voltage DC source means. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to frequency synthesizer devices and, in particular,
to such devices using a phase-locked loop (PLL) comprising a voltage
control oscillator (VCO), a phase comparator and a reference frequency
oscillator.
A typical known frequency synthesizer using the PLL, as shown in FIG. 1,
comprises a VCO 11, a variable frequency divider 12 which frequency
divides the output frequency of the VCO 11, a reference frequency
oscillator 13, and a phase comparator 14 which phase-compares between the
output from the divider 12 and the reference frequency from the reference
frequency oscillator 13 to apply the detected phase-difference signal to
the VCO 11 as a control signal.
Generally, a DC amplifier 15 is provided between the output of the phase
comparator 14 and the VCO 11 in order to amplify the phase-difference
signal.
The variable frequency divider 12 is given a desired number information (N
is a positive integer) by a suitable means and provides a signal having a
frequency of 1/N of the input frequency value.
Accordingly, the output frequency f.sub.0 of the VCO 11 is maintained at a
frequency of N times of the reference frequency f.sub.r. Therefore, a
desired frequency can be selected by selecting the number of N to be given
to the variable frequency divider.
Since the reference frequency oscillator is, usually, a crystal oscillator
with a high frequency stability, the oscillating frequency of the VCO is
stabilized.
The known frequency synthesizer has been used, for example, as a local
oscillator in a FM receiver, because of the high frequency stability.
But the known frequency synthesizer has a disadvantage that the variable
frequency divider is very expensive because it is required to have a high
dividing precision.
Another disadvantage is that the frequency selection is hardly possible by
a continuous operation such as rotating operation of a selection dial.
SUMMARY OF THE INVENTION
An object of this invention is to provide a frequency synthesizer device
using a PLL but using no variable frequency divider.
Another object of this invention is to provide a frequency synthesizer
device using a PLL wherein the oscillating frequency of the VCO in the PLL
is selected by a continuous operation of a selection dial.
A further object of this invention is to realize the above objects with a
simple, economical, compact and useful construction.
According to this invention, a frequency synthesizer comprises a PLL
including a VCO, a reference frequency oscillator, means for providing a
series of harmonic waves of a reference frequency signal from a reference
frequency oscillator and a phase comparator for detecting a
phase-difference between the output from said VCO and the harmonic waves
to apply the phase-difference signal to the VCO as a control signal. The
VCO is provided with means for coarsely changing the output frequency of
the VCO to a desired frequency. The synthesizer further comprises first
gate means coupled with the output of the VCO, counter means for counting
the number of output waves from the VCO through the first gate means,
first latching means coupled with an output of the counter means
corresponding to the least digit column of the decimal number, second gate
means connected in a closed loop of the VCO and the phase comparator,
means for providing a gate signal to open the second gate means at a time
when the number from the first latching means is in a predetermined range,
second latching means coupled with the counter means, first indicator
means for indicating the desired frequency value correspondingly to the
counted number through the second latching means, and means coupled with
the output from the reference frequency oscillator for providing a gate
pulse to open the first gate means, latching signals to operate the first
and second latching means and a reset signal to reset the counter means.
The gate pulse has a pulse width predetermined and corresponding to the
reference frequency and is repeatedly generated with a constant period.
The latching signals are provided just after each gate pulse turns off and
the reset signal is generated after the latching signal.
A digital-analogue (D/A) converter means for converting the number from the
first latching means into a corresponding analogue signal and means for
applying the analogue signal to the VCO as a voltage control signal may be
additionally provided.
The coarse frequency changing means may be a variable condenser which is
connected in parallel with a control element or a variable capacity diode
in the VCO, or a variable voltage DC source which is applied together with
the control signal to the VCO.
The PLL may be of a type wherein the output of the VCO is mixed with the
harmonic waves at a mixer, the mixed output being phase-compared with an
IF frequency signal. The IF frequency signal must be selected at a
frequency of integer times of the reference frequency value.
Further objects and features of this invention will be understood from
following descriptions in conjunction with preferred embodiments referring
to annexed drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a block diagram of a typical known frequency synthesizer
device,
FIG. 2 shows a block diagram of an embodiment according to this invention,
FIG. 3 shows a block diagram of a modified PLL in the embodiment in FIG. 2,
FIG. 4 shows waveforms in various points in FIG. 2,
FIG. 5 shows a block diagram of an example of the timing circuit in FIG. 2,
FIG. 6 shows a characteristic of a digital to analogue converter suitable
for use in the system of FIG. 2, and
FIG. 7 shows a block diagram of another embodiment, but only a portion
different from FIG. 2 being illustrated.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
Referring to FIG. 2, which shows an embodiment of this invention, the
embodiment comprises a modified PLL comprising a VCO 11, a reference
frequency oscillator 13, a monostable multivibrator 16 coupled with the
output of the reference frequency oscillator 13 for providing a series of
harmonic waves, a phase comparator 14 for comparing the oscillating
frequency of the VCO with the harmonic waves to apply a detected
phase-difference signal to the VCO 11 as a control signal through a DC
amplifier 15.
Only a portion of the modified PLL is shown in FIG. 3, with same reference
numerals being used.
Referring to FIG. 3, when the reference frequency of the oscillator 13 is
f.sub.r, the harmonic waves of the multivibrator 16 is represented as
##EQU1##
Therefore, the oscillating frequency f.sub.0 of the VCO is stabilized at a
frequency of n.multidot.f.sub.r. Therefore, if the oscillating frequency
of the VCO 11 is continuously changed, it is stabilized at each frequency
of f.sub.0 = n.multidot.f.sub.r (n = 1, 2 . . . N).
As a means for continuously changing the oscillating frequency of the VCO,
a variable condenser C.sub.v is used. The variable condenser is provided
in parallel with a frequency control element, or a variable capacity diode
D.sub.c in the VCO.
As another means for continuously changing frequency of the VCO, a variable
DC voltage source may be used, the voltage of which is applied to the
frequency control element in the VCO by adding to the control signal from
the phase comparator.
In the embodiment in FIG. 2, the variable DC voltage source is shown by 17,
and an adder is shown by 18.
Back to FIG. 2, a gate 19 is provided between the output of the VCO 11 and
an input of the phase comparator 14 to control operation of the PLL. The
gate 19 may be provided between the phase comparator 14 and the DC
amplifier 15, or between the DC amplifier 15 and the adder 19.
Another gate 20 is coupled with the output of the VCO 11 to apply the
output waves to a counter 21, which counts input waves during a period
when the gate 20 is open.
The counter 21 comprises two counter portions 211 and 212. The first
counter 211 counts by decimal numbers of one digit and the second counter
212 counts the carry signals from the first counter 211. Therefore the
first counter 211 is for the least significant digit of decimal numbers of
the count by the counter 21 and the second counter 212 is for the more
significant digits. The first counter 211 will be referred as "lowest
digit counter" and the second counter 212 will be referred as "higher
digits counter".
The outputs of both counters 211 and 212 are connected to latching circuits
23 and 23'.
A timing circuit 24 is provided for generating a gate pulse to open the
gate 20, a latching signal to operate the latching circuits 23 and 23' and
a reset signal to reset the counter 21.
The timing circuit 24 is coupled with the output of the reference frequency
oscillator 13 and provides the gate pulse having a pulse width determined
according to the frequency of the reference frequency wave. The gate pulse
is repeatedly generated with a constant interval.
The latching signal is generated just after each gate pulse ends, or turns
off, and the reset signal is developed ater the latching signal but before
the next gate pulse.
Accordingly, the output waves of the VCO 11 are counted at the counter 21
during a determined time period repeatedly at intervals of a constant
period, and the counted number is maintained at latching circuits 23 and
23' after each counting operation of the counter 21.
Referring to FIG. 4, the gate pulse G.sub.p has a pulse width equal to the
period T.sub.r of the reference frequency wave f.sub.r as shown. In this
case, the number k counted at the counter 21 during the period T.sub.r
represents the value of f.sub.0 /f.sub.r.
The number k is maintained at latching circuits 23 and 23' by the latching
signal L.sub.p which is generated just after the gate pulse G.sub.p ends,
and, thereafter, the reset pulse R.sub.p resets the counter 21.
When the next gate pulse is generated, a similar counting operation is
begun and the similar operation is repeated.
An example of the timing circuit 24 which provides gate pulse G.sub.p,
latching signal L.sub.p and reset signal R.sub.p with a time relation as
shown in FIG. 4, is shown in FIG. 5.
Referring to FIG. 5, a Schmitt trigger circuit 241 provides a square wave
signal from a sine wave signal of the reference frequency wave f.sub.r
from the oscillator 13. The output from the Schmitt trigger circuit 241 is
applied to a differential circuit 242 and, thereafter, is rectified at a
rectifier 243. The rectified signal is applied to a flip-flop circuit 244,
from which the gate pulse G.sub.p as shown in FIG. 4 is provided.
The output from the flip-flop circuit 244 is, also, applied to a
differential circuit 245 and, thereafter, is rectified at a rectifier 246.
The rectified signal is applied to a delay circuit 247, from which the
latching signal L.sub.p as shown in FIG. 4 is provided.
The output from the delay circuit 247 is, also, applied to another delay
circuit 248, from which the reset signal R.sub.p is provided as shown in
FIG. 4.
Referring to FIG. 2, an indicator 22 is connected to the latching circuit
23' to indicate the number counted in the higher digits counter 212.
Therefore, if the gate pulse has a pulse width equal to the period T.sub.r
of the reference frequency wave f.sub.r, the indication of the indicator
22 represents the value k = f.sub.0 /f.sub.r approximately, although the
number of the lowest digit of k is not indicated.
If the indicator 22 is desired to indicate frequency value, a multiplier
may be provided before the latching circuit 23', which gives
m.multidot.f.sub.r (m is the number counted at the higher digits counter
212).
If the reference frequency f.sub.r is 10.sup.n Hz, it will be noted that
the number counted at the higher digits counter directly gives an
approximate value, or a value of higher digits, of the oscillating
frequency f.sub.0 of the VCO. Therefore no multiplier must be used.
Furthermore, if the gate pulse width is determined to be a value which is
not equal to the period T.sub.r of the reference frequency wave f.sub.r,
it will be understood that a provision of multiplier means before the
latching circuit 23' enables the frequency indication by the indicator 22.
The indicator 22 is not required to indicate all digits of the number
counted by the higher digits counter 212.
The variable voltage DC source 17 is provided with a dial scale 171 to
coarsely indicate, or to indicate numbers of higher orders of, selected
frequencies. In that case, the indicator 22 indicates values of such lower
orders which cannot be sufficiently indicated. Therefore, the higher
digits counter 212 does not have a sufficient capacity for providing the
number of the all input pulses during the counting period.
The output of the latching circuit 23 is connected to a code discriminator
27 which discriminates whether the number from the latching circuit 23 is
within a predetermined range, for example, the numbers 9, 0 and 1. The
range is determined correspondingly to a locking range of the PLL.
When the number is 9, 0 or 1, the discriminator 27 provides a signal to
open the gate 19.
Thus, the PLL is placed in an operating condition, the oscillating
frequency of the VCO is stabilized at the instant frequency, which is
indicated by indicators 17 and 22.
If the number from the latching circuit 23 is not any one of 9, 0 and 1,
the PLL is not placed in operating condition. The operation of the
variable voltage DC source will bring into the operating condition of the
PLL.
Preferably, a digital-analogue (D/A) converter 25 may be provided at the
output of the latching circuit 23 to provide an analogue signal
corresponding to the number from the latching circuit 23. The analogue
signal is applied to the VCO 11 to automatically control the oscillating
frequency thereof so as to bring the number from the latching circuit 23
into zero (0). Thus, the oscillating frequency is varied steply by the
continuous operation of the variable voltage DC source 17.
An example of a characteristic of the D/A converter 25 is shown in FIG. 6.
When the number from the latching circuit 23 is within 9-1, or any one of
9, 0 and 1, the output of the converter 25 is zero volts. When it is
within 6-8, the voltage of the output of the converter 25 is negative and
its level is corresponding to the number. When the number is within 2-5,
the voltage of the output has a positive level corresponding to the
number.
The positive level and the negative level are determined by the
characteristic of the VCO 11.
A DC amplifier 26 is for amplifying the output from the D/A converter.
FIG. 7 shows another embodiment of this invention. This embodiment is
similar as the embodiment shown in FIG. 2 except for the PLL arrangement.
Accordingly, the portion of the PLL arrangement is only shown with the
other circuit members being omitted for the simplification. Similar parts
are represented by same reference numerals.
Referring to FIG. 7, the output of the VCO 11 is mixed with the harmonic
waves at a mixer 29. The output from the mixer 29 is applied to the
phase-comparator 14 through an amplifier 30.
The gate 19 is connected between the amplifier 30 and the phase comparator
14, to usually break the operation of the PLL.
The phase comparator 14 compares the output from the mixer 29 with an
output from an IF frequency oscillator 31.
The frequency f.sub.IF of the IF frequency oscillator 31 is selected to be
a value of a times (a is an integer) of the reference frequency f.sub.r of
the reference frequency oscillator 13. Therefore, the IF frequency wave
may be provided through a frequency multiplier from the reference
frequency oscillator 13.
The output of the phase comparator 14 is applied to the VCO 11 as a control
signal through the DC amplifier 15 and the adder 18.
The output of the VCO 11 is coupled with gate (20, in FIG. 2). The output
of the reference frequency oscillator 13 is coupled with timing circuit
(24, in FIG. 2). An input terminal of the adder 18 is coupled with the
variable voltage DC source (17, in FIG. 2) and the other terminal is
coupled with the D/A converter (25, in FIG. 2) through DC amplifier (26,
in FIG. 2).
In this PLL arrangement, the output frequency f.sub.0 of the VCO 11 is
stabilized at a frequency as given by following equation:
f.sub.0 = nf.sub.r - f.sub.IF = (n - a)f.sub.r
where, n = 1, 2, 3 . . . N.
Accordingly, it will be easily understood that this embodiment operates
similarly to the embodiment shown in FIG. 2. Therefore further description
of this embodiment is omitted for simplification.
This invention has been described in conjunction with preferred
embodiments. But this invention is not restricted to those specific
embodiments, but various modification and designation are easily made by
those skilled in the art within the scope of this invention.
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