Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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INTEGRATED CIRCUIT
The present invention relates Lo a semiconductor
integrated circuit and more particularly to a C~10S or
similar type of circuit when used in a frequency divider
circuit ("pre-sealer").
In many high frequency radio receivers a synthesiser
and a voltage controlled oscillator are required to
generate the local carrier signal that is used to perform
a first demaulation of the received high frequency radio
signal. However, the synthesiser is generally unable to
take the high frequency carrier signal directly as an
input. Therefore a pre-sealer must be used to divide the
carrier frequency down to a frequency that can be
accepted by the synthesiser. A pre-sealer circuit
generally comprises a number of divide by 2 circuits and
some control logic to provide, for example, a divide by
16 or 17 circuit. Each divide by,2 circuit generally
2o comprises a pair of latch circuits connected in a master
slave configuration.
In a conventional CMOS latch circuit capable of
lower frequency operation, a signal on the data input is
passed through to the output while the clock signal is
ZS hiqh_ When the clock signal goes low the latch maintains
the same output until the clock signal goes high again,
when a new data value is allowed through. The
conventional CI~OS latch compri ses two i nvPrters connected
in series and two transmission gates. The data input of
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the latch is connected to the input of the first inverter
through one of the transmission gates. The output of the
second inverter (which is also the output of the latch)
is fed back t~ the input of the first inverter through
the other transmission gate. To prevent the feedback and
the data input interfering with each other, the two
transmission gates are driven by antiphase clock signals
such that when one is open the other is closed.
The maximum frequency at which the latch can be
clocked depends on the speed at which the transmission
gates can open and close, and of course the propagation
delay through the inverters. The CMOS transmission gates
require to be driven with clock signals having
substantially the full swing of the power supply voltage
between states. The maximum operating frequency of a
c.:MC75 latch is therefore in practice much lower than that
of a latch constructed in a suitable high frequency
bipolar technology such as ECL. Furthermore, cMOS
circuits consume a lot of power at high frequencies,
2D therefore, when high speed pre-sealers are required
bipolar technology is invariably used, whereas for low
speed digital devices Ct40S or other MOS technology is
often preferred. In applications where both high speed
and low speed digital functions are required, it is
therefore commonly necessary to employ two separate
chips, one using CMOS technology for performing the low
speed digital functions and the other using bipolar
technology for performing high speed digital and analogue
functions. The need for two separate chips increases the
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cyst and size of the final product. Alternatively, a
more complex and expensive IC process which supports both
bipolar and CMOS transistors could be used.
According to one aspect, the present invention
S provides a frequency divider circuit comprising a number
of amplifier stages connected in series with the output
of a terminating amplifier stage connected to the input
of a preliminary amplifier stage and modulating means
responsive to an input signal to be frequency divided,
t0 for modulating the propagation delay through each of the
amplifier stages such that when the propagation delay
through one set of amplifier stages increases, the
propagation delay through the other amplifier stages
decreases.
15 The present invention also provides a semiconductor
latch comprising: a data input, a data output, a clock
input, two inverters connected in a memory arrangement
with the output of one connected to the input of the
other and input means connected to the memory arrangement
20 for writing new data applied to the data input into said
memory arrangement, independence upon a clock signal
applied to said clock .input, characterised in that the
latch couiprises varying means for varying the time taken
for new data to be written into said memory arrangement.
ZS The present invention also provides a method of
frequency division using a number of amplifier stages
connected in series with the output of the last amplifier
stage connected to the input of the first amplifier
stage, the method comprising: modulating the propagation
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delay through each of the ampl if ier stages such that when
the propagation delay through a given group of amplifiers
stages increases, the propagation through another group
of amplifier stages decreases.
The frequency divider or Iatch circuit embodying the
present invention can be used in many applications. For
example, it can be used to generate a local carrier in a
radio receiver circuit.
Embodiments of the invention will now be described,
by way of example only, with reference to the
accompanying drawings in which:
Figure la shows a latch circuit according to a first
embodiment of the present invention;
Figure lb shows a logic equivalent circuit of the
latch circuit shown in Figure la;
Figure 2 shows t.~o of the latches shown in Figure la
cascaded together and connected to form a divide by 2
frequency divider;
Figure 3 is a generalised equivalent circuit of the
frequency divider shown in Figure 2, with each latch
being represented by a differential amplifier with
hysteresis and a modulation block;
Figure 4 shows a frequency divider circuit according
to a second embodiment of the present invention;
?.5 Figure 5 schematically sh~WS the inpnt/~utput
relationship of the differential amplifiers with
hysteresis used in the second embodiment;
Figure 6 shows a second embodiment of a latch
circuit that may be employed in the frequency divider
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circuit shown in Figure 4;
Figure 7a is a circuit diagram that demonstrates how
the latch circuit shown in Figurs la can be modified to
provide additional logic functions;
5 figure 7b shours a logic equivalent circuit of the
latch circuit shown in Figure 7a;
Figure 8 is a circuit diagram showing a divide by
four/five circuit using latch circuits according to
embodiments of the present invention;
1~ r~~igure 9 shows a simplex frequency modulated radio
transmitter and receiver for digital data of relatively
low bit rate, according to an embodiment of the present
invention.
Figure la shows a latch circuit generally indicated
by reference numeral 10, according to an embodiment of
the present invention and Figure lb shows a logic
equivalent circuit thereof. The latch has clock inputs
CL~K, a data input D, a complementary data input DB, a
data output Q and a complementary data output QB. In the
present description and drawings, the suffix ~B" is used
throughout to indicate the complement of a given logic
signal such that. when c~ = 0, QB = 1 and vice versa.
In the circuit of Figure ta, p-channel Mos
transistor P1 and n-channel MOS transistor N1 form a
first CMOS inverter 1 with input Q and output QB and p
channel transistor P2 and n-channel transistor N2 form a
second inverter 3 with input QB and output Q. The two
inverters 1 and 3 are connected in an arrangement similar
to a standard static memory cell, with the output of one
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connected to the input of the other, as shown in Figure
lb. This is in contrast to the more typical CMOS latch
using transmission gates, described above. The circuit
also comprises two pairs of n-channel transistors
connected in series (N3 and NS; N4 and N6) each of which
perforn~s a HAND type function having inputs D and CLK,
and DB and CLK respectively, and outputs pB and Q
respectively. These two NAND type circuits are
represented by NAND gates 5 and 7 in the logic equivalent
circuit shown in Figure lb, and will be referred to
hereinafter as NAND gates 5 and 7. However, as these
skilled in the art will appreciate, these circuits do not
form complete CMOS HAND gates.
In operation, provided CLK remains low, the positive
feedback connection between inverters 1 and 3 maintains
the latch in whatever is its present state (g low/QB
high) or p high/QB law). when CLR goes high, however,
the state of the latch can be changed, depending on the
data inputs D/DB. For example, if a logic high is on gB
and a logic high is applied to CL1C while D is high, then
QH is forced to a logic low. Similarly, if a logic high
is on 0 and a logic high is applied to CLR while DB is
high, then O is forced to a logic low. When CLK goes low
again, the new state is preserved.
The n-channel transistors N1 and N2 of the two
inverters 1 and 3 are made "weaker" than the transistors
in th a corresponding HAND gate 7 and 5 that drives them,
so r_hat the logic level within the memory cell
arrangement can be overwritten_ This is achieved in the
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present embodiment by reducing the width to length ratio
(aspect ratio) of the transistors N1 and N2 compared to
the aspect ratio of transistors N3, N5 and N9, N6. Table
1 below lists suitable dimensions for each of the
transistors shown in Figure IA, in 0.7 um and 0.5 um
processes as alternatives. The transistors N3, N4
responsive to the clock signal CLR are made particularly
"strong".
Table 1
Transistor width : Length Width : Length
( 0. 7 jrm Process( D. 5 Frm Process
) )
P1 6 . 1 8 : 0.5
P2 6 . 1 B : 0.5
Nl 2.2 . 0.7 2.2 . 0.5
N2 2.2 . 0.7 2.2 . 0.5
N3 32 . 0.7 32 . 0.5
N4 32 . O.7 32 . 0.5
N5 6 : 0.7 8 : 0,5
N6 I 6 . 0.7 8 . 0.5
-
The propagation delay through the latch 10 is
dependent upon the time taken to force either 9 or QB
into a logic low after D/DB changes. If an analogue
signal is applied to CLK instead of a logic signal,
transistors N3 and N4 are not necessarily fully open or
fully closed, but act as variable resistances, the values
of which fluctuate in resgonse tv the clock signal (CLK) .
As a result of this fluctuating resistance, the time
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taken to force the latch 10 into each different state is
modulated and so the propagation delay through the latch
is modulated.
The inventors have found that by utilising the delay
5 modulation effect of this type of latch, a pre-sealer
circuit can be made which is capable of operating at much
higher frequencies than those currently available in
current cMOS technology. In particular, by applying an
oscillating signal to the CLK input, the propagation
10 delay can be modulated successfully even at a frequency
which is far too high for normal "digital" operation of
the latch.
Figure 2 shows r_wo such latch circuits l0a and 10b
connected together to form a divide by 2 frequency
divider. The Q and QH outputs of the first latch l0a are
connected to the D and DB inputs respectively of the
second latch lOb, and the Q and QB outputs of the second
latch 1Db are connected to the DB and D inputs
respectively of the first latch 10a. The input signal
2D (IN) whose frequency is to he divided is applied to the
clock input cLtc of the first latch 10a, and an antiphase
version (I27B) of the input signal to be divided i.9
applied to the clack input CLK oI the second latch lOb.
The signals iN and INB oscillate with a certain amplitude
about a voltage midway between logic high and low levels.
Connected in this manner, the circuit acts as a ring
oscillator and a chain of logic high and logic lows
propagate rnund. The rate at which the logic high and
logic lows prapayate depends upon the propagation delay
3U through each latch l0a and lOb. If the delay through
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latch l0a is Tt and the delay through latch lOh is T~
then the oscillation frequency = 1/(2(T, + TZ~~.
If the delays T, and Tz are made to vary cyclically,
with frequency fi~, about a value of 1/[2f "],(i.e.
1/[2fio]<T, and Tz<1/[2f:o1) such that T1 increases when T2
decreases
and vice versa, then the logic highs and lows can only
propagate round the circuit with a delay of 2lfin. Any
signal that tries to propagate round the circuit any
l0 faster or slower than this will automatically be slowed
down or speeded up, as the case may be, due to the
alternating delay values. In this way, the circuit
becomes an oscillator locked at frequency fin/2, and
thereby forms a frequency divider, since frn is the
frequency of the input signal IN/INB. When viewed in
this way, the operation of the circuit can be likened to
a so-called parametric amplifier.
The inventors have established that by performing
the frequency division operation in this manner, a CMOS
2U pre-sealer circuit cyan operate, at frequencies (fi") up to
about 600 IdHz, using only a conventional 0.7 arm CMOS
process_ The ability to operate at these frequencies
permits the integration of more functions on a single
chip.
To explain how the frequency divider shown in Figure
2 operates at a di fferent level , i t i s useful to consider
each latch l0a and lOb as being a differential amplifier
with hystsresis having a modulation input that can be
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used to vary the propagation delay through the amplifier.
Tn this embodiment, the modulation input amplitude
modulates the inputs applied to the amplifiers, while the
hysteresis remains constant.
5 Figure 3 is an equivalent circuit diagram of the
frequency divider shown in Figure 2 with each latch l0a
and lOb being represented by a differential amplifier
with hysteresis 30a and Sob and a modulation block 33a
and 33b as described above. Modulation block 33a is
10 driven by the input signal (IN) to be divided and
modulation block 33b is driven by the inverse (INB) of
the input signal to be divided.
As mentioned above, the modulation blocks 33a and
33b act as means for varying~the propagation delay of
each amplifier, which is achieved in this embodiment by
varying the reststance of clock transistors N3/N4 in
series with input transistors NS/N6, effectively varying
the strength of connection from one amplifier to the
other. If the strength of the connection is reduced
between amplifier 30a and amplifier 30b then it will take
longer for the signal to propagate through the amplifier
3Ub. On the other hand, if the strength of connection is
increased between amplifier 30a and amplifier 30b then it
will take less time for the signal to propagate through
the amplifier 30b. Similarly, the propagation delay
through amplifier 30a can be varied by changing the
strength of connection between amplifier 30b and
amplifier 30a. In this way, delay TL and Ti can be
changed by varying the strength of the connection between
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the two amplifiers.
After generalising the circuit shown in Figure 2 to
the equivalent circuit shown in Figure 3, it will be seen
that the same modulation effect ran be achieved in other
ways, t=or example by modulating the hysteresis of the
amplifiers directly as illustrated in Figures 9 and 5.
Figure 4 schematically shows the differential
ampl i f i ers wi th hysteresis connected in series and having
output Q of the second amplifier 40b connected to the DB
ld input of the first amplifier 40a, and output QB connected
to the D input of the first amplifier. The input signal
Ir1 is applied to the first amplifier 40a for varying the
hysteresis thereof and complementary input signal INB is
applied to the second amplifier 90b for varying the
hysteresis thereof.
Figure 5 schematically shows the input/output
characteristic of each amplifier 40a and 40b shown in
Figure 4 including hysteresis. The overall negative
feedback (due to the coupling from the Q output of the
ZO second stage to the DR input of the first) overcome9 the
positive feedback necessary to create hysteresis of each
latch. The effect of this is such that by c:ha~tginy the
hysteresis the effective propagation delays (T, and TZ)
through the amplifiers change, while the strength of the
connections between the amplifiers remains constant. In
particular, if delays T, and Tz are made to vary
cyclically, with frequency f;~ about a value of 1/(Zf;~),
(i.e. 1/(2E;"] < T~ and TZ > 1/(2f:~]) such that when T1
increases T, decreases and vice versa then, as in the
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first embodiment, the logic high and Lows can only
propagate around a circuit with frequency fia/2.
Figure 6 shows a latch circuit generally indicated
by reference numeral 60 which may be used to form the
amplifier shown in Figure 4, namely a latch circuit whose
hysteresis can be varied. The latch 60 is similar to
latch 10 shown in Figure la, but with the transistors
N3', N4' placed tn series with transistors N2' and N1'
respectively, rather than in series with transistors N5'
and N6' respectively.
As in the first embodiment, the ,propagation delay
through the latch 60 is dependent upon the time taken to
force either Q' or QB' into a logic low. Further, when
a high frequency signal is applied to CLK, transistors
N3' and N4' do not necessarily have time to become fully
open or fully closed, but anyhow act as variable
resistances, the values of which fluctuate in response to
the input signal (CLK). As a result of this fluctuating
resistance, the time taken to force the latch 60 into
each different state is modulated and so the propagation
delay through the latch 60 is modulated. Therefore, in
this embodiment the clock signal is effectively
modulating the propagation delay by modulating the
hysteresis of the latch circuits.
Figure 7a shows how the latch circuit shown in
Figure la can be modified to include other logic
functions (similar modifications could be made to the
latch circuit shown in Figure 6). The same reference
signs are used in Figure la so far as possible. In
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particular, Figure 7a comprises a P-channel MOS
transistor P1 and N-channel MOS transistor N1 which form
a first CMOS inverter 1 with input ø and output QB, and
P-channel transistor P2 and N-channel transistor N2 which
form a second inverter 3 with input gB and output Q. As
in the latch circuit shown in Figure la, the two
inverters 1 and 3 are connected in a standard static
memory cell arrangement with the output of one connected
to the input of the other, as shown in Figure 7b. The
latch circuit also comprises transistors N3, N6A and N6B
which together form a circuit that performs a three input
HAND type function having inputs A H and CLK and output
QH, and is represented by NAND gates 70 and 5 in Figure
7b. The circuit also comprises transistors NbA and N6B
in parallel and transistor N4 connected in series with
the parallel combination of transistors N6A and N6B. The
parallel combination of transistors N6A and N6H forms a
circuit that performs an OR type function and is
represented by OR gate 71 in Fiyure 7b. Tlie transistor
2D N4 and the above parallel combination together form a
circuit that performs a HAND type function, and is
represented by NAND gate 7 in Figure 7b.
The circuit shown in Figure 7a operates as follows.
When QH is high and inputs A, H and CLK are all high,
then QB will be forced to a logic low. Sjmilarly, when
p is high and either (i) input AB (complement oL A) and
CLI( are high or (ii} input (counplement of B) HH and CLK
arc high, then Q will be forced to a logic low. In other
words, the output of the latch (ø) will be low unless
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both inputs A and H are high When CLK is high.
Therefore, the latch circuit shown in Figure 7a
effectively comprises a D-type latch whose Data input is
a logical awo function of inputs A and B.
As those skilled in the art will appreciate, the
addition of the extra logic circuitry will not affect the
principle of operation of the latch circuit when employed
in a frequency divider circuit. Therefore, the latch
circuit can be employed in more complex counter circuits
and still maintain the speed advantage over the known
devices.
Figure 8 shows an example of a pre-sealer circuit
that can perform a divide by four or divide by five
operation. The circuit as shown comprises four Latch
circuits of the type shown in Figure la or Figure 6 (L2,
h3, L4 and L6 ) and two latch circuits of the AND gate
type shown in Figure 7a (L1 and L5). A control input
CTRLICTR.LB is connected to the H/HB input of latch L5.
The circuit will divide by four when the CTRL, is low and
will divide by five when the CTttL is high and can operate
at frequencies up to about 450MHz from 3V supplies and up
to 600 MHz at SV, on a 0.7 arm prcx:ess. The pzinciple of
operation of the circuit is the same as that of the
divide by two circuit shown in Figure 2, and will not be
described again.
All of the latches LI to L5 are clocked by the input
signal IN/INH whose frequency is to be divided.
Alternatively, the counter circuit could eornprise a
plurality of divide by two circuits, like those shown in
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Figure 2, connected in series with the output of one
divide by 2 circuit being applied to the clock input of
the next adjacent divide by two circuit. This has the
advanr_age that later stages can be dimensioned for lower
5 speed and lower current operation, but is limited to
powers of two in the choice of division factors. gy
providing division factors of four and five (2z and 2z +
1) with suitable control logic, any integer division
factor greater than 4 x 5 can be achieved.
10 Figure 9 shows an application for the novel
frequency divider circuits in the form of a simplex
frequency modulated (FM) radio transmitter and receiver
generally indicated by reference numeral 90, for digital
data of relatively low bit rate. Applications of such a
I5 radio include mobile pagers, and also in future data
transmission for control and metering of utilities such
as gas and electricity supplies. The general structure
of the transmitter/receiver is of a form well-known to
those skilled in the art and will not be described in
depth.
Referring to Figure 9, when data is to be
transmitted it is first modulated in modulation block 91
using a data modulating technique such as quadrature
phase shift keying (OPSK) and then supplied to the input
of a voltage controlled oscillator (VCO) 93. The output
of the VCO 93 is a radio frequency (RF) signal modulated
by the QFSK signal which is then amplified by a power
amplifier 95 and broadcast from an antenna 97 via a
transmit/receive control switch 99 and filter lUl.
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When data is to be received, RF input signals picked
up by the antenna 97 are filtered in filter l0I to remove
noise and passed to an RF amplifier 103 via the
transmit/recei.ve control switch 99. The amp=ified
signals are then filtered again in a filter 105 to remove
unwanted carrier signals that might result in "image
signals" at an IF stage. A mixer 107 converts the RF
input signals down to intermediate frequency (IF) signals
by multiplying the incoming RF signals by a locally
generated carrier signal. The IF signals at the output
of the mixer 107 are then filtered again by a ceramic
resonator or similar filter 109 which has a flat response
over the required bandwidth and large attenuation either
side of the passband. The received data is then
retrieved by demodulating the IF signal output from the
ceramic filter 109 in a demodulation block 111.
Although it is very effective as a filter, the
centre frequency of the ceramic type filter 109 has a
fixed value. It is not possible to vary this centre
frequency in order to re-tune the radio r_o other carrier
frequencies, and at the same time maintain the required
attenuation on either side of the passband. The solution
to this problem is to ensure that the lb' signals at the
output of the mixer 107 are always centred at the same
frequency. Therefore, to receive other modulated
carriers, the local carrier signal applied to the mixer
107 must be variable to convert the desired RF signals
down to the fixed IF frequency.
'This is conventionally achieved by using a voltage
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controlled oscillator (vCO) 93, a pre-scalar 113 and a
digital frequency synthesiser 115 connected in the manner
shown in Figure 5. The frequency of the output signal
from the vC0 93 is controlled by the input voltage
thereto supplied by the synthesiser I15, while r_he
synthesiser receives a version of the VGO output signal,
frequency divided by the pre-scalar 113.
Frequency division is conventionally thought of as
a digital function and the maximum frequency the pre
scalar 113 can reduce depends on the digital circuit
technology used. With RF input signals, bipolar
transistor technology is normally used which can operate
at the high RF frequencies. however, when a low cost,
low power CMOS chip is used for the synthesiser 115 (and
perhaps also for the data decoding, processing and
control operations of the receiver as a whole), this
results in the need for a second chip for performing the
frequency division, which increases the cost and size of
the transmitter/recei.ver 9U. In contrast, the pre-scalar
103 in the transmitter/receiver of Figure 9 uses the
novel frequency divider described above. By this
feature, every part of the simplex transmitter/receiver
9U, with the possible exception of the analog filters,
can be built into a single MoS integrated chip, thereby
reducing the overall cost and size of the data
transmitter/receiver 90. The mixer I07 can be
implemented by MOSFET transistors also integrated on the
same chip.
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