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| United States Patent |
5,537,241
|
|
Fisher
|
July 16, 1996
|
Telecommunications system
Abstract
Error-free or rapid protection switching between two basestations, one main
and one standby, or two transmitters (1,2) etc. of one basestation (8) is
achieved using a downstream marshalling scheme involving the transmission
of a sequence from the standby basestation to an outstation (9,10,11) at
levels below the noise sensitivity of a receiver (7) at the outstation and
alignment of the phases of the transmitted sequence and a reference main
basestation sequence by, for example, a correlation process. If a similar
upstream marshalling process is employed for marshalling additional
outstations into the system the same circuitry can be used for phase
alignment for both marshalling processes. (FIG. 1).
| Inventors:
|
Fisher; David A. (Saffron Waldon, GB3)
|
| Assignee:
|
Northern Telecom Limited (Montreal, CA)
|
| Appl. No.:
|
562083 |
| Filed:
|
November 15, 1995 |
Foreign Application Priority Data
| Nov 12, 1992[GB] | 9223746 |
| Jun 22, 1993[GB] | 9312909 |
| Current U.S. Class: |
398/99; 398/8; 398/100; 398/154; 398/168 |
| Intern'l Class: |
H04J 014/08; H04B 010/00 |
| Field of Search: |
359/110,135,136,137,158,167,168
|
References Cited [Referenced By]
U.S. Patent Documents
| 5063595 | Nov., 1991 | Ballance | 359/152.
|
| 5278690 | Jan., 1994 | Vella-Coleiro | 359/158.
|
| 5327277 | Jul., 1994 | Van der Plas et al. | 359/158.
|
| 5341365 | Aug., 1994 | Clarke | 359/110.
|
| 5357360 | Oct., 1994 | Imhoff et al. | 359/137.
|
| Foreign Patent Documents |
| 0163311 | Dec., 1985 | EP | 371/8.
|
| 0272916 | Nov., 1990 | JP | 340/825.
|
| 9317506 | Sep., 1993 | WO | 455/103.
|
Primary Examiner: Boudreau; Leo
Assistant Examiner: Mehta; Bhavesh
Attorney, Agent or Firm: Lee, Mann, Smith, et al.
Parent Case Text
This application is continuation of application Ser. No. 08/152,279, filed
Nov. 12, 1993, now abandoned.
Claims
I claim:
1. A method of enabling error free or rapid protection switching between a
main base station and a standby base station serving a plurality of
outstations in a time division multiple access (TDMA) telecommunications
system in which downstream traffic from the main base station to said
outstations is transmitted in frames and in which each said outstation has
means for receiving a binary sequence, said receiving means having a
decision threshold whereby to distinguish one and zeros in that binary
sequence, the method including providing each said frame with a window
within which transmission of data from the main base station is
temporarily suspended and within which the main base station transmission
Dower level is reduced to approximately one half transmitting from said
standby base station to a said outstation during each said window a
reference binary sequence having an amplitude that is small relative to
the main base station transmission, said reference sequence being a
pseudo-random sequence and being superimposed on the main base station
transmission, determining at the outstation the relative numbers of binary
ones and zeros detected in the reference sequence and adjusting the power
of the main base station transmitter relative to the decision threshold of
the outstation receiving a means so that the relative numbers of ones and
zeros detected in the reference sequence by the receiving means are
substantially equal, determining at the outstation from the timing of said
reference sequence relative to the timing of the main base station
transmissions the magnitude of a phase difference between the main base
station and the standby base station transmissions, and adjusting the
timing of the standby base station such that transmissions from both base
stations received at the outstation are in phase.
2. A method as claimed in 1, wherein the phase alignment is achieved by a
correlation process.
3. A method as claimed in claim 2, Wherein in the telecommunications system
additional outstations are introduced into the system by transmitting from
each additional outstation a respective reference sequence at a level
below the noise sensitivity of a receiver of the base station, detecting
said respective reference sequence at the base station, discriminating the
phase of the detected respective reference sequence and using the
discriminated phase to determine a loop delay to the additional
outstation.
4. A method as claimed in claim 3, wherein the sequence from the additional
outstation and its phase are detected by a correlation process.
5. A method as claimed in claim 2, wherein the main and standby
transmitters are given identical frame synchronisation information and the
relative delay between the main transmitter sequence and a correlation
sequence is used to determine the required standby transmitter transmit
time.
6. A method as claimed in claim 1, wherein the main and standby base
stations each include a respective transmitter which is transmitting
continuously, the base station acting as a main base station at a
particular point in time transmitting at a higher power than the base
station acting as a standby base station at that time.
7. A method as claimed in claim 6, wherein the ratio of transmitted powers
of the main and standby base stations is of the order of 10:1.
8. A method as claimed in claim 7, wherein the telecommunications system is
a passive optical network (PON) system and wherein the transmitters are
optical sources.
9. A method as claimed in claim 8 applied to a burst mode system in which
the downstream and upstream directions may share the same optical fibre
and transmit in bursts so that at no time is a transmitter and receiver
pair at an outstation or at a base station transmitting at the same time.
Description
This invention relates to telecommunications systems and in particular to
systems employing the time division multiplex/time division multiple
access (TDM/TDMA) principle:
BACKGROUND OF THE INVENTION
The TDM/TDMA principle is well known in radio systems or passive optical
networks (PONs), where it is employed to permit transmission between a
single basestation and a plurality of outstations. In the downstream
(basestation to outstation) direction, the information (traffic) is
broadcast to all outstations, but upstream it is transmitted in bursts,
each of which must be timed to avoid mutual interference (overlap) so that
at any time the basestation only receives data from one outstation.
In our co-pending GB Applications 931291 1.2 and 9312910.4 (D A Fisher
10-2-1 and D A Fisher 11-3) there are described time division multiple
access frame alignment techniques for use in marshalling the transmission
from newly connected outstations without interfering with existing traffic
transmissions. The basic method of these applications comprises employing
pseudo random sequences at a level below the noise sensitivity of the base
station receiver (for normal traffic). These sequences can be detected
using correlation and their phase is used to determine the loop delay to
the new outstation. A sequence generator is required at the outstation,
and a reference generator is required at the basestation for correlation
process. This is an upstream marshalling technique. The present invention
is concerned with protection of the basestation.
SUMMARY OF THE INVENTION
According to the present invention there is provided a method of enabling
error free or rapid protection switching between two basestations, a main
basestation and a standby basestation, in a telecommunications system,
which method employs a downstream marshalling scheme involving the
transmission of a sequence from the standby basestation to an outstation
at levels below the noise sensitivity of a receiver at the outstation and
alignment of the phases of the transmitted sequence and a reference main
basestation sequence in advance of switching between standby operation and
main operation.
It is thus proposed to use an extension of a downstream marshalling
technique in order to provide seamless protection i.e. enable switching
from one basestation to another. A downstream window can be used to
capture samples. Initial alignment to the nearest bit can be achieved
using exactly the same circuitry as for upstream marshalling. Samples can
be stored at the outstations and processed thereat or at a basestation.
Duplicated traffic routes can be phase aligned either by allowing the
marshalling technique to achieve it or, alternatively, if the phase
discriminator of the marshalling system is modified to give an indication
of the phase difference, alignment can be obtained more quickly.
The method may be applied to a burst mode system in which the downstream
and upstream directions may share the same optical fibre and transmit in
bursts so that at no time is a transmitter and receiver pair at an
outstation or basestation transmitting at the same time, and in respect of
marshalling sequences upstream and marshalling sequences may be concurrent
and continuous but orthogonal in nature or neither process will be
concurrent in which case orthogonality is not required.
BRIEF DESCRIPTION OF THE DRAWINGS
Embodiments of the invention will now be described with reference to the
accompanying drawings in which:
FIG. 1 illustrates a PON network, and
FIG. 2 illustrates the optical signal at the receiver.
DESCRIPTION OF PREFERRED EMBODIMENT
The network illustrated in FIG. 1 comprises a basestation 8 and three
outstations 9, 10 and 11. Outstation 11 is drawn more explicitly than
outstations 9 and 10 but all three are identical. This basic PON network
and its function and the upstream marshalling technique is described in
greater detail in the first above-mentioned co-pending application. The
present invention is described hereinafter with reference to a PON network
but it should be understood that it is equally applicable to a radio
network or a twisted pair of coaxial cable network operating on TDMA
principles.
The passive optical splitter 12 which includes a transmitter and receiver
parts splits the signal out of a single transmitter e.g. TX1(1) into
several receivers e.g. receiver 7 of outstation 11 so that the basestation
8 can be carrying all of the traffic for everybody connected to it. With
32 outstations this can be up to six or seven hundred circuits, since each
outstation can carry of the order of thirty channels. Hence quite often it
is necessary to protect the basestation by duplicating it. For the case
where the basestation electro-optical components have been duplicated as 1
and 2 the splitters 12 will be unchanged but there are now two fibres 3
and 4 running to it rather than just fibre 3. There is a need to be able
to switch from one basestation transmitter 1 to the other transmitter 2
and for this it is necessary for them to be perfectly synchronous and of
similar amplitude, which would be the case if the fibres were exactly the
same length and had the same loss. In practice this is not possible and
thus some means is required to align their phases such as by means
illustrated as variable delays 5. One way of doing this is to align the
delays of the two fibres so that a receiver at an outstation can be
switched instantaneously from one transmitter to the other, i.e. one
basestation to the other, so that operation can be continuous i.e. one
transmitter is a hot standby transmitter. This can be achieved using a
marshalling process with one (main) transmitter operating all the time.
There is a small window in the downstream TDM frame structure of the main
transmitter which is used for messaging but which is unused most of the
time, and this window can be used to capture samples, alternatively a
fixed window in the downstream frame may be reserved. The standby
basestation transmitter also transmits a low level transmission, which
transmissions are similar to those described in the above-mentioned
co-pending application as output by the outstation, which any of the
outstations can receive and may store values (samples) of and possibly
perform local processing on. However since the cost of a basestation is
amortised over all the outstations it is preferable to perform all the
processing at the basestation end of the system. The outstation stored
values can be sent to the basestation for processing using a dedicated
channel or shared upstream channel, and processed by exactly the same
circuitry that would be used for upstream marshalling as described in
detail in the above-mentioned applications and thus by using the same
techniques you can adjust the phase of the transmitted signal from one
basestation to the nearest bit at least, to be the same as the other
basestation. Having done that it is necessary to adjust the phase to
within a bit for which there are three possible techniques. Technique 1
does not employ the marshalling process to achieve this since once the
basestations have been switched over the phase acquisition circuit 6 would
acquire phase relatively quickly. Technique 2 uses the phase discriminator
in the optical receiver of the outstation 7 modified to give an indication
of exactly the phase difference between the phase of normal transmission
and the phase of the offset one, for example by observing the location of
zero crossings in a short burst of 10101010 traffic sent from the standby
transmitter at normal amplitude, and if that is known the phase of the
offset one can be modified so as to exactly align the phase and position
in the frame of both of them. The third technique employs the coefficients
of the correlators integrating the standby basestation transmission. Hence
phase alignment of duplicated traffic routes i.e. hot standby switchover
is achieved. This is an extension of the marshalling technique of the
above mentioned applications to allow hot standby protection switching
without any error introduction.
Aspects of the downstream marshalling system used to obtain hot standby
switchover will now be described in greater detail.
The amplitude of the low level transmitter sequence from the standby
basestation must be relatively small compared to that of the main
basestation transmission, in order that there is a negligible effect on
the ability of an outstation to receive the main basestation transmission
free of error. For example, a rate of approximately 10:1 in optical power
is sufficient to meet this condition, although a greater ratio may be
employed. Consequently during the downstream marshalling window in which
the main transmitter output is temporarily suspended, in order for the
outstation to be able to detect the standby transmitted sequence, it is
necessary for the outstation receiver threshold to be at the centre of the
standby transmitter signal deviation. In order to achieve this it is
necessary either to provide a special receiver design in which the
outstation receiver threshold during the downstream marshalling window is
able to adjust to the mean level of the signal during the window, or to
design the main and standby transmitters in such a way as to allow this
condition to be met. In a passive optical network employing this
technique, it is advantageous to modify the transmitter rather than a
multiplicity of receivers. This also allows the outstation receiver design
to be entirely conventional, having a threshold recovery circuit that is
adjusted to the mean of the optical data signal, which is normally binary.
The method and means for achieving the requirement is as follows.
Attention is directed to FIG. 2 in this respect.
During the downstream marshalling window, the main transmitter is set to
approximately the half power level. An optical transmitter conventionally
transmits at full power for a binary one and reduced power for a binary
zero. The binary zero power is often that corresponding to the laser bias
level, in which the laser is driven by a bias current, whilst the binary
one level is determined by being driven by the bias current and a drive
current. Thus to obtain half power the bias current is not altered but the
drive current is halved. During the marshalling window, the optical signal
received at each outstation will consist of the half power level of the
main base station transmission, with the much lower standby transmitter
sequence superimposed on it. This is illustrated in FIG. 2. The double
headed arrows indicate the deviation of the received signal from the main
transmitter due to the standby transmitter. In FIG. 2 the receiver
decision threshold is a little too low, since the threshold during the
downstream marshalling window is not at the centre of the deviation and is
unlikely to produce any binary zeros.
In order to allow for the tolerance in the receiver decision threshold
determined from the received signal, for deviation in the relationship
between the laser drive current and output power, and tolerance in the
laser drive circuit, a further technique for adjustment of the drive
current of the main transmitter during the downstream marshalling window
may be necessary. This takes the form of a control loop in which the ratio
of ones and zeros received during the downsteam marshalling window is
determined and the transmitter drive current adjusted until this balances,
this assuming equal probability of the number of ones and zeros in the
standby correlation sequence. The mechanism for returning the outstation
received data to the basestation may employ a part of the PON TDMA
upstream frame from that outstation, one method being to share the
upstream messaging channel using the data received during a downstream
marshalling window in place of a null message content. Since the
correlation process operates over several thousand samples, the loss of
some of these samples does not affect the function, but will increase the
overall acquisition time.
The outstation receiver design is thus conventional and operation during
the downstream marshalling window is thus no different from that elsewhere
in the downstream frame, the sampled part of the downstream marshalling
window may consist of only 8 bits of information, with a period of 16 bits
either side to allow for the main transmitter to be switched from full to
half power and half to full power, plus a short sequence of normal power
alternating one/zero transmission prior to and after the marshalling
window to ensure timing recovery circuits remain in good alignment in
respect of the main transmitter.
In the downstream marshalling method the main and standby transmitters will
be given the same frame synchronisation reference information in order
that the relative delay between the main transmission sequence to the
outstation, which will contain framing information, for example in the
form of a CRC in a fixed position, and the correlation sequence position
can be used to determine the required standby transmitter transmit time.
In order to determine the required transmit phase angle for the standby
transmitter (phase angle being defined as the fraction of a transmitted
bit) in addition to the delay in bits between the two paths (main to
receiver and standby to receiver), employing technique 3 referred to
earlier it is sufficient to determine the correlation coefficients of two
correlators spaced one bit apart in respect of the reference sequence. If
the standby transmitted sequence is not an exact number of data bits (in
delay terms e.g. 1 bit at 50MHz represents a delay of 20 nanoseconds
representing a differential transmission distance of 4 metres) then the
sampled sequence will be comprised of samples in which components from the
two adjacent bits from the standby transmitter exist. Conversely, each
element transmitted by the standby transmitter will have a component in
two adjacent receiver samples. When averaged (integrated) over sufficient
received bits, the ratio of the adjacent correlation coefficients will
give the degree of offset of the bit boundary. This may be adjusted by
means of an adjustable tapped delay line at the standby transmitter until
there is no overlap of coefficients. The outstation receiver in the
conventional case will detect a binary one or binary zero, hence if the
phase error relative to the bit boundary is small, the larger signal
component will dominate and potentially totally obscure the smaller signal
component, preventing the assessment of the ratios of adjacent correlator
coefficients. Where the received standby is comparable with or smaller
than transmitter correlation sequence level is comparable with the noise
level of the receiver, this limiting effect will not apply. However if
this is not the case, an alternative is to deliberately adjust the phase
of the standby transmitted sequence to generate equal components in
adjacent samples. When the standby transmitter is switched to become the
main transmitter, the required phase angle and bit offset is applied.
During standby operation, once the relative position of the transmitter has
been found, short bursts of normal amplitude data may be transmitted in
the marshalling window to enable verification and full power adjustment of
the standby transmitter.
* * * * *
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