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| United States Patent |
5,581,387
|
|
Cahill
|
December 3, 1996
|
Optical data communications network with a plurality of optical
transmitters and a common optical receiver connected via a passive
optical network
Abstract
An optical data communications network, for example a TPON
(telecommunications over passive optical networks) network, has a common
optical receiver and a plurality of optical transmitters connected to the
common optical receiver by a passive optical network which consists of
optical splitters/combiners linked by lengths of an optical fibre. The
optical signals produced respectively by the different optical
transmitters are interleaved together in a predetermined time-division
multiple access format and are modulated using a return-to-zero modulation
format. The common optical receiver can operate satisfactorily at
desirably-high bit rates despite wide variations in the power levels of
the optical signals reaching the receiver from the different transmitters,
which variations arise due to the different attenuations experienced by
those signals as they propagate along optical fibre paths of different
lengths containing different numbers of splitters/combiners. As a result,
power levelling of the transmitters is not required.
| Inventors:
|
Cahill; Neil (Ashby De La Zouch, GB)
|
| Assignee:
|
Fujitsu Limited (Kanagawa, JP)
|
| Appl. No.:
|
580044 |
| Filed:
|
December 20, 1995 |
Foreign Application Priority Data
| Current U.S. Class: |
398/100; 398/1; 398/99; 398/168; 398/202 |
| Intern'l Class: |
H04J 014/08 |
| Field of Search: |
359/135,136,137,189,168
|
References Cited [Referenced By]
U.S. Patent Documents
| 5063595 | Nov., 1991 | Ballance | 359/137.
|
| 5107361 | Apr., 1992 | Kneidinger et al. | 359/137.
|
| 5305333 | Apr., 1994 | Kaylor et al. | 372/26.
|
| 5325225 | Jun., 1994 | Suzaki et al. | 372/26.
|
| 5353143 | Oct., 1994 | Clarke | 359/135.
|
| Foreign Patent Documents |
| 0216214 | Apr., 1987 | EP.
| |
| 0122036 | Jul., 1984 | JP | 359/187.
|
| 0151039 | Jul., 1987 | JP | 359/187.
|
| WO8604205 | Jul., 1986 | WO.
| |
| WO8805233 | Jul., 1988 | WO.
| |
| WO91/06157 | May., 1991 | WO.
| |
Other References
English translation of European Patent appln. (UK) No. 0216214, date of
translation Aug. 14, 1991.
|
Primary Examiner: Boudreau; Leo
Assistant Examiner: Mehta; Bhavesh
Parent Case Text
This is a continuation of application Ser. No. 08/285,239, filed Aug. 3,
1994, now abandoned.
Claims
What we claim is:
1. An optical data communications network comprising:
a common optical receiver; and
a plurality of optical transmitters connected to said common optical
receiver by way of a passive optical network;
wherein optical signals produced respectively by the different optical
transmitters are interleaved together in a predetermined time-division
multiple access format and are modulated using a return-to-zero modulation
format;
said passive optical network and/or said optical transmitters being such
that optical signals received by the common optical receiver from one of
said optical transmitters are substantially unequal in power to optical
signals received by the common optical receiver from another of said
optical transmitters,
wherein the use of the return-to-zero modulation format permits the common
optical receiver to cope with wide variations in the received power levels
from different optical transmitters.
2. A network as claimed in claim 1, wherein said common optical receiver
includes:
opto-electronic conversion means arranged for receiving said optical
signals and operative to convert those received optical signals into a
corresponding electrical signal having a DC signal component upon which AC
data signals, corresponding to said optical signals, are superposed; and
signal processing means DC-coupled to said opto-electronic conversion means
for receiving said electrical signal and operable to produce an output
signal dependent upon the difference between said electrical signal and a
predetermined bias signal.
3. A network as claimed in claim 2, wherein said signal processing means
are operable, during a quiet phase of the network when none of said
optical transmitters is producing an optical signal, to store said
electrical signal produced at that time, and are operable thereafter to
employ that stored signal as said predetermined bias signal.
4. A network as claimed in claim 3, wherein said signal processing means
include:
a differential amplifier circuit having a first input connected for
receiving said electrical signal produced by the opto-electronic
conversion means; and
a sample-and-hold circuit having a sampling input connected to an output of
the differential amplifier circuit and also having a holding output
connected to a second input of the differential amplifier circuit;
said sample-and-hold circuit being activated to sample the output signal of
the differential amplifier circuit during said quiet phase so that during
that phase the sample-and-hold circuit completes a negative feedback loop
between said output and said second input of the differential amplifier
circuit, whereby said output signal tends to substantially the same value
as said electrical signal at said first input, and being deactivated, at a
predetermined instant in the quiet phase, to hold at said holding output
the value of said output signal at that instant so that thereafter the
output signal value produced by the differential amplifier circuit is
dependent upon the difference between the value of the electrical signal
at the first input and the holding output value.
5. A network as claimed in claim 4, wherein said common optical receiver
further includes:
comparator means connected to said output of the differential amplifier
circuit for comparing said output signal value with a threshold value; and
threshold value generating means connected to said sample-and-hold circuit
for deriving said threshold value from said holding output value.
6. A network as claimed in claim 5, wherein said common optical receiver
further includes mean power detection means arranged for providing a
measure of the mean value of said electrical signal, said measure being
employed by the threshold value generating means to increase said
threshold value, relative to said holding output value, when said mean
value is relatively high and to decrease that value, relative to said
holding output value, when said mean value is relatively low.
7. A network as claimed in claim 1, being a
telecommunications-over-passive-optical-networks (TPON) network operating
according to a bit transport system (BTS).
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to optical data communications networks, in
particular but not exclusively to a TPON (telecommunications over passive
optical networks) network.
2. Description of the Prior Art
In a TPON network, a network head-end station (for example in a telephone
exchange) is linked to plurality of remote terminations (for example
street distribution points) by a passive optical splitting network (PON).
There may be separate PONs for the downstream (head-end to terminations)
and upstream (terminations to head-end) data directions.
In the TPON network, according to a bit transport system (BTS) proposed by
British Telecommunications PLC, in the downstream direction data is
broadcast by the head-end station to all the terminations in the network
in a time division multiple access (TDMA) multiplexed frame. In the
upstream direction, each termination transmits a data pulse in a
predetermined time slot so that the data pulses reaching the head-end
station from the different terminations are interleaved to form an
upstream TDMA frame having a predetermined format.
The link loss (optical attenuation), between a termination and the head-end
station, may vary considerably from one termination to another in
dependence upon the distance of the termination concerned from the
head-end station and upon the number of optical splitters through which
the optical signal from the termination must pass to reach the head-end
station. This means that, assuming all of the terminations transmit their
data pulses at the same optical power level, the interleaved upstream data
pulses reaching the head-end station will vary significantly from one
another in optical power.
Heretofore it has been thought that it would not be possible for the
head-end station optical receiver to cope with such wide variations in
received optical power levels, and accordingly, in a trial system, the
optical output power level of each termination was controlled
individually, for example in dependence upon control data included in the
downstream TDMA frame broadcast to the terminations by the head-end
station, so as to achieve more uniformity in the received optical power
levels at the head-end station.
Such individual control of the terminations, however, is undesirable in
that it increases the complexity, and hence the cost, of the
opto-electronic equipment at each termination. The cost of the
terminations is often a critical element in the feasibility of any
network. Moreover, the need to transmit control data in the downstream
TDMA frame, at least on initialisation of a termination and probably at
intervals during use thereof to overcome drift, may result in slow
initialisation and can generally reduce the time available for
transmission of data.
BRIEF SUMMARY OF THE INVENTION
According to the present invention there is provided an optical data
communications network including a common optical receiver and a plurality
of optical transmitters connected to the said common optical receiver by
way of a passive optical network, wherein optical signals produced
respectively by the different optical transmitters are interleaved
together in a predetermined time-division multiple access format and are
modulated using a return-to-zero modulation format, the said passive
optical network and/or the said optical transmitters being such that
optical signals received by the common optical receiver from one of the
said optical transmitters differ in power from those received by the
receiver from another of the said optical transmitters.
In such a network, the use of return-to-zero (RZ) modulation format enables
the common optical receiver in the head-end station to cope with wide
variations in the power levels of the optical signals reaching the
receiver from the different terminations. In the trial system mentioned
above, on the other hand, a nonreturn-to-zero (NRZ) modulation format was
used, which, as explained hereinafter in more detail, effectively made it
impossible for the common optical receiver to cope with the received power
level variations in a practical network.
The common optical receiver preferably includes opto-electronic conversion
means, arranged for receiving the said optical signals and operative to
convert those received optical signals into a corresponding electrical
signal having a DC signal component upon which AC data signals,
corresponding to the said optical signals, are superposed. Signal
processing means are DC-coupled to the opto-electronic conversion means
for receiving the electrical signal and are operable to produce an output
signal dependent upon the difference between the electrical signal and a
predetermined bias signal. In such a receiver, because the opto-electronic
conversion means are DC-coupled to the signal processing means, problems
of baseline wander due to variations in the received power levels from
different transmitters, are overcome.
The opto-electronic conversion means may, for example, be a PINFET
receiver, in which case the DC signal component is a DC bias signal
arising from biassing arrangements for the PINFET receiver.
The predetermined bias signal, which should be set in dependence upon the
DC signal component of the electrical signal, can be fixed but, in a
preferred embodiment, the signal processing means are operable, during a
quiet phase of the network when no upstream-direction transmitter is
producing an optical signal, to store the electrical signal produced at
that time, and are operable thereafter to employ that stored signal as the
above-mentioned predetermined bias signal. Such an arrangement permits
satisfactory operation even if the DC signal component of the electrical
signal varies, for example with time and temperature. It also avoids the
need for presetting the DC signal component at each termination.
In one such arrangement, the signal processing means include a differential
amplifier circuit having a first input connected for receiving the
electrical signal produced by the opto-electronic conversion means, and
also include a sample-and-hold circuit having a sampling input connected
to an output of the differential amplifier circuit and a holding output
connected to a second input of the differential amplifier circuit. The
sample-and-hold circuit is activated to sample the output signal of the
differential amplifier circuit during the quiet phase so that during that
phase the sample-and-hold circuit completes a negative feedback loop
between the output and the second input of the differential amplifier
circuit, whereby the output signal tends to substantially the same value
as the said electrical signal at the said first input. The sample-and-hold
circuit is then deactivated, at a predetermined instant in the quiet
phase, to hold at its holding output the value of the said output signal
at that instant so that thereafter the output signal value produced by the
differential amplifier circuit is dependent upon the difference between
the value of the electrical signal at the first input and the holding
output value. Such an arrangement makes effective use of a single
differential amplifier circuit and sample-and-hold circuit to achieve the
required signal storage and amplification functions.
In the above arrangement, after the quiet phase the input of the
differential amplifier is referenced to the holding output value. In view
of this, the common optical receiver advantageously includes comparator
means connected to the output of the differential amplifier circuit for
comparing the output signal value thereof with a threshold value, and also
includes threshold value generating means connected to the sample-and-hold
circuit for deriving the threshold value from the said holding output
value. Thus, the threshold value tracks changes in the holding output
value, for example so as to overcome problems that would otherwise be
caused by variations in the holding output value due to long term drift of
temperature and/or supply voltages etc. over many multiframes.
The common optical receiver preferably further includes mean power
detection means arranged for providing a measure of the mean value of the
said electrical signal, that measure being employed by the threshold value
generating means to increase the said threshold value, relative to the
holding output value, if the mean value is relatively high and to decrease
the threshold value, relative to the holding output value, if the mean
value is relatively low. Such a receiver can operate over a wider range of
received optical powers than its inherent (adaptive) power range.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a block diagram of a TPON network;
FIG. 2 shows a diagrammatic representation of an upstream TDMA multiframe
in the TPON network of FIG. 1;
FIG. 3 shows a block diagram of a TPON network having terminations at
widely differing distances from a head-end station of the network;
FIG. 4A shows a timing diagram illustrating a modulation format used in a
previously-considered TPON network;
FIG. 4B shows a timing diagram illustrating a modulation format used in a
TPON network embodying the present invention;
FIG. 5 shows a block diagram of receiving circuitry for use in a TPON
network embodying the present invention; and
FIG. 6 shows a diagram for illustrating an advantageous feature of the FIG.
5 circuitry.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
A TPON network, as shown in FIG. 1, includes a network head-end station 1
located at a central site which may, for example, be a telephone exchange.
The network also includes a plurality of terminations 2 which may, for
example, be located respectively at street distribution points.
In the example shown in FIG. 1, two separate passive optical splitting
networks (PON) 3 and 4 are used to link the network head-end station 1 to
the terminations 2. The PON 3 is used to convey optical signals in the
downstream direction, from the network head-end station 1 to the
terminations 2. The PON 4 is used to convey optical signals in the
upstream direction, from the terminations 2 to the network head-end
station 1.
Each PON 3 or 4 includes lengths of optical fibre 5 and passive optical
splitters 6. The maximum distance between a termination 2 and the head-end
station 1 is typically less than 10km, but could be up to 20km.
The head-end station 1 includes a common optical transmitter 10 for
launching optical signals into the PON 3 for the downstream direction, and
a common optical receiver 11 for receiving optical signals from the PON 4
for the upstream direction. Similarly, each termination 2 includes an
optical transmitter 12 for launching optical signals into the appropriate
branch of the upstream PON 4, and an optical receiver 13 for receiving
optical signals from the appropriate branch of the downstream PON 3.
Data is transmitted over the PONs 3 and 4 in accordance with a bit
transport system (BTS) proposed by British Telecommunications PLC. In the
downstream direction, data is broadcast by the common optical transmitter
10 in the head-end station 1 to all the terminations 2 in the network in a
time-division multiple access (TDMA) multiplexed frame (multiframe). Each
of the terminations 2 is arranged to be responsive to the broadcast
optical signals only in its predetermined time slot(s) within the
downstream multiframe.
In the upstream direction, the optical transmitter 12 of each termination 2
transmits optical data pulses in predetermined time slots allocated to the
termination concerned so that the optical data pulses reaching the
head-end station 1 from the different terminations 2 are interleaved to
form an upstream TDMA multiframe having a predetermined format as shown in
FIG. 2.
The upstream TDMA multiframe is of duration 10ms and, apart from an initial
portion or header used for ranging purposes, consists of bit- or
byte-interleaved data from the different terminations 2, organised into a
series of basic frames (BF1 to BF80) each consisting of 2496 bits in
total, of which 2352 bits are allocated to data (payload bits) and the
remaining 144 bits are used for network control purposes (housekeeping
bits). The bit rate in the upstream PON is 20.48Mbit/s, so that the bit
period is approximately 48.8ns. In order to maximise the data transfer
rate, there are no gaps between the interleaved bits or bytes from the
different terminations 2, that is to say, at the end of the bit period for
one termination (or the end of the byte for one termination in the case of
byte interleaving) the next-transmitting termination becomes active
immediately in the next bit period.
The distances of the terminations 2 from the head-end station 1 in a TPON
network can vary significantly from one another. For example, in an
extreme case as shown in FIG. 3, the first termination 2.sub.1 is only
500m from the head-end station 1, and the optical path between the
termination 2.sub.1 and the head-end station 1 involves only one optical
splitter 6. On the other hand, the second termination 2.sub.2 is 5km from
the head-end station 1 and the optical path between the termination
2.sub.2 and the head-end station 1 involves four optical splitters 6. The
attenuation in the optical path between the head-end station 1 and the
termination 2.sub.2 is therefore much greater than that between the
head-end station 1 and the termination 2.sub.1. Assuming a 3dB loss in
each splitter 6, then even neglecting fibre loss, the attenuation in the
path to the head-end station 1 from the termination 2.sub.2 will be 9dB
greater than in the corresponding path from the termination 2.sub.1.
Assuming that the terminations 2.sub.1 and 2.sub.2 are assigned successive
time slots in the upstream TDMA multiframe, then unless the transmitting
power levels of the optical transmitters 12 in the terminations 2.sub.1
and 2.sub.2 are adjusted appropriately, the received optical power at the
common optical receiver 11 of the network head-end station 1 will be 9dB
or more greater in the time slot t.sub.1 for the termination 2.sub.1 than
in the succeeding time slot t.sub.2 for termination 2.sub.2. Such widely
disparate power levels in successive bit periods were found to cause
problems for the optical receiver in the head-end station, as explained
below with reference to FIG. 4A.
In FIG. 4A, the data modulation format employed in a previously-considered
TPON network is represented. The format employed is nonreturn-to-zero
(NRZ), which requires that a symbol "1" is transmitted as a pulse
P.sub.NRZ of uniform high light level for the full duration of a time slot
(bit period). The interleaved optical pulses are received by the optical
receiver in the head-end station and converted, by opto-electronic
conversion circuitry, into a corresponding electrical signal E, for
example as shown in the lower portion of FIG. 4A. The opto-electronic
conversion circuitry response time is such that the transitions in the
electrical signal E are subject to some degree of rounding. Thus, as FIG.
4A shows, following a "1" symbol in time slot t.sub.1, in the time slot
t.sub.2 the electrical signal decays relatively slowly towards the zero
level.
The response of the opto-electronic conversion circuitry to a pulse
P'.sub.NRZ of lower power is shown in dotted lines in the lower portion of
FIG. 4A. In further circuitry of the receiver, the level of the electrical
signal E is compared with a predetermined threshold TH level to
distinguish between the "0" and "1" light levels. If power levelling is
not performed, the predetermined threshold level TH must be set to a
suitably low value bearing in mind that it must be less than the highest
value of the electrical signal E for the weakest optical pulse which it is
desired to detect, as represented for example by the pulse P'.sub.NRZ in
dotted lines in FIG. 4A. The slow decay of the electrical signal E means
that, if the "1" symbol in time slot t.sub.1 is from a strong transmitter
(pulse P.sub.NRZ), a "0" symbol in the next time slot t.sub.2 (either from
the same transmitter or from another transmitter) may be mistakenly
interpreted as a "1" symbol because for at least the initial portion of
the time slot t.sub.2 the electrical signal E exceeds the threshold value.
To overcome this problem, in a previously-considered TPON network which
underwent a trial by British Telecommunications PLC, the solution adopted
was to provide for individual adjustment of the optical output powers of
the different terminations. By boosting the optical output power of
distant terminations relative to those of near terminations, it was
possible to compensate for the different path attenuations involved and so
ensure that the successive optical pulses received by the head-end station
receiver 11 were of sufficiently uniform amplitude. This permits a higher
threshold value to be chosen.
By contrast, a TPON network embodying the present invention can avoid the
need for individual control of the optical output powers of the
terminations, even when the terminations vary in distance from the
head-end station receiver by as much as from 50m to 10km, as explained
below with reference to FIG. 4B.
In a TPON network embodying the present invention, the modulation format
used is return-to-zero (RZ), as shown in FIG. 4B. In this modulation
format, a symbol "1" is transmitted as a pulse P.sub.RZ having a high
light level for only an initial part of the time slot (bit period), for
example the first half of the time slot, whereafter the low or zero light
level is transmitted for the remainder of the time slot. The corresponding
electrical signal derived by the opto-electronic conversion circuitry in
the head-end station optical receiver is shown in the lower portion of
FIG. 4B. At the start of the time slot t.sub.2, the electrical signal E
produced by the high power pulse P.sub.RZ has an amplitude lower than the
predetermined threshold level TH (set, as before to permit detection of
the weaker pulse P'.sub.RZ), so that no data error results in time slot
t.sub.2.
Thus, the use of RZ modulation format can enable the head-end station
optical receiver to cope effectively with optical pulses of widely
different power levels in adjacent time slots, without requiring complex
arrangements for adjusting the individual optical output power levels of
the terminations or very fast opto-electronic conversion circuitry in the
head-end optical receiver.
FIG. 5 shows a preferred example of receiving circuitry for use in the
common optical receiver 11 of a TPON network embodying the present
invention. The receiving circuitry 20 includes an optical receiving
circuit comprising a transimpedance 20Mbd PINFET type receiver 21,
including a photodiode 22 formed on a common substrate with an FET
amplifier 23, having an output voltage of a few millivolts at its
sensitivity limit of -48dBm (peak), and a maximum output voltage of around
1 volt at saturation. The bias current for the photodiode is filtered.
The output voltage V.sub.i of the PINFET receiver 21 is filtered by a low
pass filter 24.
Due to the design of the FET amplifier in the PINFET receiver 21, the
filtered output voltage V.sub.i sits at a DC bias level of -1 to -1.5
volts in the absence of any received optical signal. When optical pulses
are received from a termination, these are converted into corresponding AC
data pulses which are superimposed on this DC bias component. These AC
data pulses must be amplified before application to decision circuitry of
the receiver used to regenerate the received data.
Previously-proposed receiving circuitry for use in TPON networks has
employed AC-coupling between the PINFET receiver 21 and a subsequent
amplifier stage used for performing such amplification, since such
coupling serves to prevent the above-mentioned DC bias component of the
output voltage of the PINFET receiver 21 from being applied to the input
of the amplifier stage. However, in such an AC-coupled receiver subsystem,
baseline wander tends to occur unless the received optical pulses in the
upstream TDMA multiframe are sufficiently uniform in optical power and
occurrence.
To avoid problems associated with baseline wander the receiving circuitry
20 of FIG. 5 provides a completely DC-coupled receiver subsystem, which
includes a non-linear gain block 25.
The gain block 25 receives at a first input I.sub.1 thereof the filtered
output voltage V.sub.i of the PINFET receiver 21, and receives at its
second input (I.sub.2) a predetermined bias voltage V.sub.bias
corresponding to the DC component of the output voltage V.sub.i. The gain
block 25 includes a differential amplifier circuit, constituted by an
amplifier element 26 and resistors R.sub.1 and R.sub.2, whose input is
referenced to V.sub.bias.
Upper and lower predetermined clamping voltages V.sub.max and V.sub.min are
applied to the amplifier 26, for reasons explained hereinafter.
The gain block 25 serves to subtract from the output voltage V.sub.i of the
PINFET receiver 21 the predetermined bias voltage V.sub.bias and to
amplify the difference between the voltages V.sub.i and V.sub.bias such
that the gain block 25 amplifies the AC data pulses but not the DC bias
component in the PINFET receiver output voltage V.sub.i.
The predetermined bias voltage V.sub.bias may be derived from a fixed
voltage source but, as the DC bias component of the PINFET receiver output
voltage V.sub.i varies from one receiver to another and also drifts with
time and temperature, preferably the bias voltage V.sub.bias to be
employed by the gain block 25 is established by the circuitry when first
turned on and is then adjusted periodically as necessary during operation
of the circuitry.
The receiving circuitry 20 therefore further includes a sample-and-hold
circuit 27 having a sampling input connected for sampling the output
voltage V.sub.o of the gain block 25 and a hold output connected to the
second input of the gain block 25. The sample-and-hold circuit 27 is
activated to sample the voltage V.sub.o at its sampling input by a control
signal DC-CLAMP provided by control circuitry 28 of the optical receiver
11 during an initial portion of each upstream TDMA multiframe, as
described below in more detail.
The receiving circuitry 20 further includes a high-speed comparator circuit
29 having a first input connected to receive the output voltage V.sub.o of
the gain block 25 and a second input connected to receive a threshold
voltage V.sub.th provided by a threshold voltage generating circuit 31.
The threshold voltage generating circuit 31 is also connected to the hold
output of the sample-and-hold circuit 27 for receiving the bias voltage
V.sub.bias. The threshold voltage generating circuit 31 has a further
input for receiving a monitoring signal POWER provided by a mean power
detection circuit 33. The circuit 33 receives as an input the filtered
output voltage V.sub.i of the PINFET receiver 21.
In operation of the receiving circuitry 20 of FIG. 5, the DC-CLAMP control
signal is applied by the control circuitry 28 to the sample-and-hold
circuit 27 during the quiet phase in the initial portion of each upstream
TDMA frame (see FIG. 2). During this quiet phase, no correctly-operating
termination is producing optical pulses, and therefore the output voltage
V.sub.i of the PINFET receiver contains no AC data pulses and has only its
DC bias component which is normally in the range from -1 to -1.5 volts.
Whilst the control signal DC-CLAMP is active, the output voltage V.sub.o
of the amplifier element 26 in the gain block 25 is fed back, via the
sample-and-hold circuit 27, to the second (inverting) input I.sub.2 of the
gain block 25, so that a negative feedback loop exists between the output
and input of the gain block 25. This negative feedback loop eventually
causes the bias voltage V.sub.bias at the inverting input I.sub.2 of the
gain block 25 to assume a level close to (for example within 3 millivolts
of) that of the PINFET receiver output voltage V.sub.i received during the
quiet phase at the first (non-inverting) input I.sub.2 of the gain block
25, i.e. V.sub.bias becomes substantially equal to the DC bias component
of the PINFET receiver output voltage.
Once the quiet phase of each multiframe is over, the control circuitry 28
deactivates the control signal DC-CLAMP, so that the negative feedback
loop between the output and input of the gain block 25 is broken, and
V.sub.bias is stored in the sample-and-hold circuit 27. Thereafter, as
mentioned above the gain block 25 operates as a differential amplifier in
which the stored bias voltage V.sub.bias is subtracted from the output
voltage V.sub.i of the PINFET receiver 21 and the difference voltage
(V.sub.i -V.sub.bias) is then amplified.
Incidentally, since the quiet phase in each upstream TDMA frame is quite
short (approximately 15 microseconds), when the receiving circuitry 20 is
initially turned on it may take a number of multiframes for the correct
value of the bias voltage V.sub.bias to be stored in the sample-and-hold
circuit 27. This, however, is of little practical consequence in view of
the fact that, at the time the network is turned on, it normally takes
several multiframes for the remaining parts of the network, for example
the terminations, to be operating correctly anyway.
The maximum gain of the differential amplifier is set by the ratio of the
resistors R.sub.1 and R.sub.2 as 1+R.sub.1 /R.sub.2, for example the
maximum gain may be around 36. This maximum gain cannot be applied to AC
data pulses corresponding to the strongest received optical pulses since
such data pulses may have an amplitude of 0.5V or more before
amplification, sending the output of the amplifier element 26 into
saturation.
For this reason, the amplifier element 26 is desirably one having DC
clamping to promote fast recovery from saturation by preventing the output
voltage V.sub.o from straying outside a range delimited by the
predetermined upper and lower clamping voltages V.sub.max and V.sub.min.
The upper clamping voltage V.sub.max may be, for example, 1 volt above the
bias voltage V.sub.bias (i.e. V.sub.max =V.sub.bias + 1 .apprxeq.0V) and
the lower clamping voltage V.sub.min may be -5V. The upper clamping
voltage V.sub.max limits the effective gain of the differential amplifier
to around 1 to 2 for AC data pulses of the maximum amplitude (0.5 to 1V),
produced by the PINFET receiver 21 in response to optical pulses from the
nearest terminations. Thus, the gain characteristic of the gain block 25
is non-linear and so the block 25 serves to produce amplified AC data
pulses of acceptably uniform amplitudes, irrespective of non-uniformity in
the received optical powers, and which are within predetermined upper and
lower limits.
Furthermore, because the bias voltage V.sub.bias tends to be substantially
the same as the DC bias component in the output voltage V.sub.i of the
PINFET receiver, the output voltage V.sub.o of the gain block 25 contains
an acceptably-low DC component even at the maximum gain (x36) thereof.
In the high-speed comparator 29 the output voltage V.sub.o of the gain
block 25 is compared with the threshold voltage V.sub.th provided by the
threshold voltage generating circuit 31. The circuit 31 is coupled to the
sample-and-hold circuit 27 and adds to the bias voltage V.sub.bias stored
in the sample-and-hold circuit 27 a variable offset voltage V.sub.os so as
to produce a threshold voltage which tracks changes in the bias voltage
V.sub.bias (i.e. V.sub. th=V.sub.bias +V.sub.os). This is advantageous
because, as noted above, the input of the differential amplifier circuit
in the gain block 25 is referenced to the bias voltage V.sub.bias.
The variable offset voltage V.sub.os is controlled in dependence upon the
monitoring signal POWER provided by the mean power level detection circuit
33. The mean power level detection circuit 33 monitors the mean value of
the output voltage V.sub.i of the PINFET receiver 21. The monitoring
signal POWER is employed by the threshold voltage generating circuit 27 in
such a way as to increase the variable offset voltage V.sub.os when the
mean value of the output voltage V.sub.i is relatively large and to
decrease that offset voltage when the mean value of the output voltage
V.sub.i is relatively low.
The ability to vary the offset voltage V.sub.os, and hence the differential
between the bias voltage V.sub.bias and the threshold voltage V.sub.th,
can be advantageous in a network in which the inherent dynamic (adaptive)
range of the receiving circuitry 20 does not cover the full required
dynamic range of the network. For example, the receiving circuitry may
have an inherent adaptive range in excess of 13dB, whereas the full
required dynamic range of the network may be from -44 to -29dBm, namely a
range of 15dB. In this case, the signal POWER provided by the mean power
level detection circuit 33 can serve as a weighting factor for adjusting
the threshold voltage V.sub.th employed by the comparator circuit 29
according to whether the average power from all the individual
terminations is toward the higher or lower end of the allowed input power
band (-44 to-29dBm). This weighting factor is illustrated in FIG. 6.
Alternatively, however, the offset voltage Vos may be fixed.
The high-speed comparator circuit 29 produces a stream of data pulses D
based on the result of the comparison between V.sub.o and V.sub.th. This
data stream D is applied to further circuitry of the optical receiver 11
in the head-end station, which further circuitry separates out the
information for each different termination.
It will be understood that, although the foregoing embodiment of the
present invention has been described in the context of a TPON network, in
other embodiments the present invention is applicable advantageously to
any optical network, particularly a TDMA network, in which it is possible
for an optical receiver to receive optical pulses that vary in power over
a short time scale.
In the example illustrated in FIG. 4B, a symbol "1" was transmitted as a
pulse having a high light level for the first half of the bit period. It
will be understood that the proportion of the bit period over which the
light level is high need not be 50%, however. In particular, it would be
possible to decrease the high light level time to less than 50%, although
this would be at the expense of the energy being transmitted in each bit
period.
* * * * *
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