![[US Patent & Trademark Office, Patent Full Text and Image Database]](/netaicon/PTO/patfthdr.gif)
| United States Patent |
5,808,766
|
|
Van de Voorde
, et al.
|
September 15, 1998
|
Method for measuring a signal transmission delay time, central station,
terminal station and network to perform this method
Abstract
The method is used in an optical transmission network with a plurality of
terminal stations (TS1-TSn) connected to a central station (CS) via a
tree-like connection structure, to determine a signal transmission delay
time between one terminal station (TSi) and the central station. The
terminal stations are adapted to send cells containing information signals
to the central station in dedicated time slots. The method consists of
sending a start signal (start CR) from the central station to the terminal
station (TSi), after a first predetermined time interval after the receipt
of that start signal sending a ranging signal from the terminal station to
the central station, after a second predetermined time interval after the
sending of the start signal sending an inhibit signal from the central
station to the terminal stations to indicate that no cells may be
transmitted during an idle time window; determining in the central station
the signal transmission delay time from the contents of the predetermined
ranging signal received by the central station during the idle time
window. The ranging signal either has an amplitude which is smaller than
the information signals contained in the cells in order not to disturb the
information signals when the ranging signal is transmitted outside the
idle time window, or has a similar amplitude, in which case error codes
are included in the cells in order to recover possible disrupted cells.
| Inventors:
|
Van de Voorde; Ingrid Zulma Benoit (Wilrijk, BE);
Bert De Groote; Jan Lieven (Berchem, BE);
Van der Plas; Gert (Merchtem, BE)
|
| Assignee:
|
Alcatel N.V. (BH Rijswijk, NL)
|
| Appl. No.:
|
718278 |
| Filed:
|
September 20, 1996 |
Foreign Application Priority Data
| Current U.S. Class: |
398/102; 370/508 |
| Intern'l Class: |
H04J 014/08 |
| Field of Search: |
359/140,136,137,118
370/508,519,443,442
|
References Cited [Referenced By]
U.S. Patent Documents
| 5299044 | Mar., 1994 | Mosch et al. | 359/161.
|
| 5327277 | Jul., 1994 | Van Der Plas et al. | 359/140.
|
| 5341365 | Aug., 1994 | Clarke | 370/508.
|
| 5559805 | Sep., 1996 | Hedderly | 370/443.
|
| 5642355 | Jun., 1997 | Smith | 370/442.
|
Primary Examiner: Pascal; Leslie
Attorney, Agent or Firm: Ware, Fressola, Van Der Sluys & Adolphson LLP, Oliver; Milton
Claims
We claim:
1. An optical network with a plurality of terminal stations TS1-TSn
connected to a central station (CS) via a tree-like connection structure,
and wherein said terminal stations are adapted to send cells containing
information signals to said central station in dedicated time slots, said
central station including means to receive a predetermined ranging signal
from one terminal station (TSi) of said plurality of terminal stations in
an idle time window during which no said cells are transmitted, said
ranging signal initially having a length or duration equal to two times a
maximum possible difference, among respective terminal stations, in
respective transmission delays between each terminal station and said
central station, and said terminal stations each including means to send
said predetermined ranging signal, characterized in that said central
station additionally includes:
means to send a start signal (start CR) from said central station to said
terminal stations;
means to send, after a first predetermined time interval after the sending
of said start signal, an inhibit signal from said central station to said
terminal stations, to indicate to said terminal stations that no said
cells are to be transmitted during said idle time window;
error recovery means to interpret error codes included in said cells by
said terminal stations and to recover said information signals in case of
corruption of said information signals due to the transmission of said
predetermined ranging signal outside said idle time window;
means to determine a signal transmission delay time, between said one
terminal station and said central station, from the contents of said
ranging signal received by said central station from said one terminal
station during said idle time window; and
wherein said terminal stations each additionally include;
means to receive said start signal from said central station sent to said
terminal stations and to send out said predetermined ranging signal, a
second predetermined time interval after the receipt of said start signal,
said predetermined ranging signal having an amplitude relatively near to
amplitude of said information signals; and
means to include said error codes in said cells.
2. A method for measuring, in an optical transmission network with a
plurality of terminal stations (TS1-TSn) connected to a central station
(CS) via a tree-like connection structure, a signal transmission delay
time between one terminal station (TSi) of said plurality of terminal
stations and said central station, said terminal stations being adapted to
send cells containing information signals to said central station in
dedicated time slots, said method including the step of
sending a predetermined ranging signal from said one terminal station to
said central station for receipt in an idle time window during which no
said cells are transmitted,
characterized in that
said terminal stations include error codes in at least some of said cells
and that said method additionally includes the steps of:
sending a start signal (start CR) from said central station to said one
terminal station (TSi);
after a first time interval after the receipt of said start signal, sending
said predetermined ranging signal from said one terminal station to said
central station, said predetermined ranging signal having an amplitude
relatively near to the amplitude of said information signals;
after a second predetermined time interval after sending said start signal,
sending an inhibit signal from said central station to said terminal
stations to indicate to said terminal stations that no said cells are to
be transmitted during said idle time window;
determining, in said central station, said signal transmission delay time
from the contents of said predetermined ranging signal received by said
central station during said idle time window,
said error codes and said predetermined ranging signal being chosen so as
to enable recovery of said information signals in case of corruption by
said predetermined ranging signal if sent outside said idle time window;
and wherein,
in a first application of said steps, where said first predetermined time
interval equals zero, the length of said predetermined ranging signal
equals L, where L equals two times the maximum possible difference, among
respective terminal stations, in respective transmission delays between
each terminal station and said central station.
3. A method according to claim 2, characterized in that said first
predetermined time interval equals a previously determined coarse value of
said signal transmission delay time, said steps then being performed to
obtain a more accurate value thereof.
4. A method according to claim 2, characterized in that said first
predetermined time interval equals zero.
5. A method according to claim 2, characterized in that said predetermined
ranging signal is composed of repetitive signals including successive
integer values.
6. A method according to claim 5, characterized in that said predetermined
ranging signal is composed of repetitive signals including successive
integer values, ranging from an initial value to a maximum value which is
a function of transmission delay between said central station and a most
distant one of said terminal stations, each of said successive integer
values is transmitted m times, where m equals L/2", 2" being the maximum
value of said successive integer values.
7. A method according to claim 6, characterized in that said idle time
window has an interval that equals two said cells and that said repetitive
signals are transmitted at the cell rate.
8. A method according to claim 7, characterized in that said steps are
repeated L/2" times, the length of said repetitive signal being divided by
2 in each repetition, thereby enabling the determination of said signal
delay time with an accuracy of one said cell.
9. A method according to claim 2, characterized in that said second
predetermined time interval equals L-1 cells, where L equals two times the
maximum possible difference in transmission delay between two said
terminal stations.
10. An optical network with a plurality of terminal stations (TS1-TSn)
connected to a central station (CS) via a tree-like connection structure,
and wherein said terminal stations are adapted to send cells containing
information signals to said central station in dedicated time slots, said
central station including means to receive a predetermined ranging signal
from one terminal station (CSi) of said plurality of terminal stations in
an idle time window during which no said cells are transmitted, said
ranging signal initially having a length or duration equal to two times a
maximum possible difference, among respective terminal stations, in
respective transmission delays between each terminal station and said
central station, and said terminal stations each including means to send
said predetermined ranging signal, characterized in that said central
station additionally includes:
means to send a start signal (start CR) from said central station to said
terminal stations;
means to sends, after a first predetermined time interval after the sending
of said start signal, an inhibit signal from said central station to said
terminal stations, to indicate to said terminal stations that no said
cells are to be transmitted during said idle time window;
means to determine a signal transmission delay time, between said one
terminal station and said central station, from the contents of said
ranging signal received by said central station from said one terminal
station during said idle time window; and
wherein said terminal stations each additionally include:
means to receive said start signal from said central station sent to said
terminal stations and to send out said predetermined ranging signal, a
second predetermined time interval after the receipt of said start signal,
said predetermined ranging signal having an amplitude which is smaller
than the amplitude of said information signals, thereby avoiding
degradation of said information signals due to the transmission of said
predetermined ranging signal outside said idle time window.
11. A central station (CS) adapted to be included in an optical network
with a plurality of terminal stations (TS1-TSn) connected to said central
station via a tree-like connection structure, and wherein said terminal
stations are adapted to send cells containing information signals to said
central station in dedicated time slots, said central station including
means to receive a predetermined ranging signal from one terminal station
of said plurality of terminal stations in an idle time window during which
no said cells are transmitted, said ranging signal initially having a
length or duration equal to two times a maximum possible difference, among
respective terminal stations, in respective transmission delays between
each terminal station and said central station, characterized in that said
central station additionally includes:
means to send a start signal (start CR) from said central station to said
one terminal station;
means to send, after a predetermined time interval after the sending of
said start signal, an inhibit signal from said central station to said
terminal stations, to indicate to said terminal stations that no said
cells are to be transmitted during said idle time window;
means to determine a signal delay time, between said one terminal station
and said central station, from the contents of said ranging signal
received by said central station from said one terminal station during
said idle time window.
12. A central station (CS) adapted to be included in an optical network
with a plurality of terminal stations (TS1-TSn) connected to said central
station via a tree-like connection structure, and wherein said terminal
stations are adapted to send cells containing information signals to said
central station in dedicated time slots, said central station including
means to receive a predetermined ranging signal from one terminal station
of said plurality of terminal stations in an idle time window during which
no said cells are transmitted, said ranging signal initially having a
length or duration equal to two times a maximum possible difference, among
respective terminal stations, in respective transmission delays between
each terminal station and said central station, characterized in that said
central station additionally includes:
means to send a start signal from said central station to said one terminal
station;
means to send, after a predetermined time interval after the sending of
said start signal, an inhibit signal from said central station to said
terminal stations, to indicate to said terminal stations that no said
cells are to be transmitted during said idle time window;
error recovery means to interpret error codes included in said cells and to
recover said information signals in case of corruption by said information
signals due to the transmission of said predetermined ranging signal
outside said idle time window;
means to determine a signal transmission delay times between said one
terminal station and said central station, from the contents of said
ranging signal received by said central station from said one terminal
station during said idle time window.
13. A terminal station (TSi) adapted to be included in an optical network
with a plurality of terminal stations (TS1-TSn) similar to said terminal
station and connected to a central station (CS) via a tree-like connection
structure, and wherein said terminal stations are adapted to send cells
containing information signals to said central station in dedicated time
slots, said terminal station including means to send a predetermined
ranging signal to said central station for receipt in an idle time window
during which no said cells are transmitted, said ranging signal initially
having a length or duration equal to two times a maximum possible
difference, among respective terminal stations, in respective transmission
delays between each terminal station and said central station,
characterized in that said terminal station additionally includes:
means to receive a start signal (start CR) from said central station to
said terminal stations and to send out said predetermined ranging signal a
predetermined time interval after the receipt of said start signal, said
predetermined ranging signal having an amplitude which is smaller than the
amplitude of said information signals, thereby avoiding degradation of
said information signals due to the transmission of said predetermined
ranging signal outside said idle time window.
14. A terminal station (TSi) adapted to be included in an optical network
with a plurality of terminal stations (TS1-TSn) similar to said terminal
station and connected to a central station (CS) via a tree-like connection
structure, and wherein said terminal stations are adapted to send cells
containing information signals to said central station in dedicated time
slots, said terminal station including means to send a predetermined
ranging signal to said central station for receipt in an idle time window
during which no said cells are transmitted, said ranging signal initially
having a length or duration equal to two times a maximum possible
difference, among respective terminal stations, in respective transmission
delays between each terminal station and said central station,
characterized in that said terminal station additionally includes:
means to receive a start signal (start CR) from said central station sent
to said terminal stations and to send out said predetermined ranging
signal a predetermined time interval after the receipt of said start
signal, said predetermined ranging signal having an amplitude relatively
near to the amplitude of said information signals; and
means to include error codes in said cells.
15. A method for measuring, in an optical transmission network with a
plurality of terminal stations (TS1-TSn) connected to a central station
(CS) via a tree-like connection structure, a signal transmission delay
time between one terminal station (TSi) of said plurality of terminal
stations and said central station, said terminal stations being adapted to
send cells containing information signals to said central station in
dedicated time slots, said method including the step of sending a
predetermined ranging signal from said one terminal station to said
central station for receipt in an idle time window during which no cells
are transmitted,
characterized in that said method additionally includes the steps of:
sending a start signal (start CR) from said central station to said one
terminal station (TSi);
after a first predetermined time interval after the receipt of said start
signal, sending said predetermined ranging signal from said one terminal
station to said central station, said predetermined ranging signal having
an amplitude which is smaller than the amplitude of said information
signals, thereby avoiding degradation of said information signals due to
the transmission of said predetermined ranging signal outside said idle
time window;
after a second predetermined time interval after sending said start signal,
sending an inhibit signal from said central station to said terminal
stations to indicate to said terminal stations that no said cells are to
be transmitted during said idle time window;
determining, in said central station, said signal transmission delay time
from the contents of said predetermined ranging signal received by said
central station during said idle time window; and wherein,
in a first application of said steps, where said first predetermined time
interval equals zero, the length of said predetermined ranging signal
equals L, where L equals two times the maximum possible difference, among
respective terminal stations, in respective transmission delays between
each terminal station and said central station.
16. A method according to claim 15, characterized in that said first
predetermined time interval initially equals a previously determined
coarse value of said signal transmission delay time, said steps then being
performed to obtain a more accurate value thereof.
17. A method according to claim 15, characterized in that said first
predetermined time interval equals zero.
18. A method according to claim 15, characterized in that said
predetermined ranging signal is composed of repetitive signals including
successive integer values.
Description
TECHNICAL FIELD
The present invention relates to a method for measuring in an optical
transmission network with a plurality of terminal stations connected to a
central station via a tree-like connection structure, a signal
transmission delay time between one terminal station of the plurality of
terminal stations and the central station, wherein the terminal stations
are adapted to send cells containing information signals to the central
station in dedicated time slots.
This invention also relates to a central station, a terminal station and an
optical network performing this method.
BACKGROUND OF THE INVENTION
Such a method, central station, terminal station and network are already
known in the art, e.g. from the European Patent Application 90890273.7.
(U.S. Pat. No. 5,107,361) Therein an optical system is described where a
terminal station after becoming active can perform its ranging procedure,
i.e. a procedure to determine the transmission delay between that terminal
station and the central station, and additionally the procedure for
obtaining its address, in a so called ranging window wherein the other
terminal stations already active do not send cells to the central station.
From this transmission delay the terminal station then determines in which
time slot it is enabled , after receipt of a grant signal from the central
station to send its information cells. This known procedure implies that
the ranging window equals at least twice the maximum transmission delay of
the network since the terminal station which becomes active is not aware
of the configuration of the network, i.e. it is not aware of the distance
between the other terminal stations and the central station and
consequently it does not know when it may send a ranging signal without
disturbing the transmission of the information signals. As a result, the
active terminals are not allowed to send information during a relatively
long period, especially since this ranging procedure is executed
periodically, either to allow activated terminals to go through a
configuration phase, or to possibly adjust the already defined
transmission delays of already active terminals.
SUMMARY OF THE INVENTION
An object of the invention is to provide a method, a terminal station, a
central station and a network realizing this method, such as the known one
but which does not have the above drawback, i.e. where there is no need
for a relatively large ranging window.
Indeed, by either sending a ranging signal with an amplitude lower than the
amplitude of the information signals or including error codes in the cells
and sending a ranging signal with an amplitude near to the amplitude of
the information signals, the ranging signal can be transmitted during the
transmission of the information signals, i.e. outside the idle time
window, called ranging window in the known method. The central station can
thus open a ranging window, by asking the terminal stations to stop
transmission of the information signals, during a time interval which is
smaller than in the known systems, provided that that the window and the
ranging signal are so chosen that at least part of the latter signal can
be received during the open window, i.e. the period of transmission of the
ranging signal has at least partly to overlap the idle time window.
Different choices can be made with respect to the length of the idle time
window, the length of the predetermined time intervals and of the type of
ranging signal. The definite choice is a trade off between the time and
the bandwidth needed for performing the ranging procedure. Indeed, the
larger the window, the more bandwidth is required, but the more
information can be received by the central station and thus the less time
is required to determine the transmission delay with a required accurracy
and vice versa. A possible choice realizing a good compromise between the
latter time and bandwidth requirements is to initially set the length L of
the ranging signal to twice the maximum possible difference in respective
delays between the central station and respective terminal stations, and
thereafter to adjust the length, based on actual delay measurements.
It should be noted that the use of error codes and of ranging signals
having an amplitude in the range of the amplitude of the information
signals is especially suited for large scale passive optical networks also
called SUPERPONs with a relatively high number of terminal stations and
relatively large distances between the terminal stations and the central
station and having a high dynamic range, and wherein due to the
amplifiers, used the amplitude of the noice signals come within the range
of the amplitude of a reduced amplitude ranging signal.
BRIEF DESCRIPTION OF THE DRAWINGS
The above mentioned and other objects and features of the invention will
become more apparent and the invention itself will be best understood by
referring to the following description of an embodiment taken in
conjunction with the accompanying drawings wherein:
FIG. 1 represents an optical network wherein a method according to the
invention is realized; and
FIGS. 2a and 2b are timing diagrams of the performance of a ranging method
according to the invention.
FIG. 3 is a functional block diagram of the central station shown in FIG.
1; and
FIG. 4 is a functional block diagram of one of the terminal stations shown
in FIG. 1.
BEST MODE FOR CARRYING OUT THE INVENTION
The network of FIG. 1 is a passive optical network or PON network over
which Time Division Multiple Access or TDMA PON cells are transmitted.
These cells (not shown) consist of a header, containing a synchronization
preamble, and a data packet.
The network includes a central station CS coupled to a plurality of
terminal stations TS1 to TSn via a common fiber link C and dedicated links
C1 to Cn. PON cells are transmitted over the network in downwards
direction from CS to the terminal stations and in upwards direction from
the terminal stations to CS in dedicated time slots. To avoid collision
between the upwards sent cells, each terminal station has to be aware of
its transmission delay, i.e. of the distance between itself and the
central station. Transmission of upstream cells is initiated by the
central station by a grant signal. Upon receipt of such a grant signal a
terminal station has to take into account a predetermined delay, called
ranging delay, before sending a cell to avoid the above mentioned
collision. This delay is such that it is as if the terminal station was
located at the maximum network distance from the central station and can
be deduced from the earlier mentioned transmission delay. The procedure
for determining the transmission delay or the ranging delay, also called
the ranging procedure, as used in the subject invention is described
hereafter with reference to FIGS. 1 and 2. As best seen in FIG. 3, the
central station includes a cell receiver and transmitter 10 connected to
the common fiber link C. The central station further includes means to
send a start signal (CR) 12 and means to send an inhibit signal 14 whose
operation is explained below. In addition, the central station includes
means to determine the signal delay time 16 from a terminal station based
upon receipt of a ranging signal from that terminal station. An
information signal recovery module 18 is used to interpret error codes
included with cells containing information signals that are generated by
terminal stations so as to recover information signals when these signals
are corrupted due to transmission of a ranging signal at least outside the
idle time window for a portion of the ranging signal's duration.
Each terminal station includes a number of functional modules as best seen
in FIG. 4. Thus a cell transmitter and receiver 20 connects to fiber link
Ci associated with the specific terminal station, where i=1,2, . . . , n.
An information signal generator 22 generates cells containing desired
information. An error code generator 24 can interface with the information
signal generator to add error codes to the cells so as to facilitate
recovery of information signal by the central station when the information
signal is corrupted by transmission of a ranging signal outside the idle
time window for a portion of its duration. Each terminal station further
includes a start signal (CR) detector and ranging signal generator 26. The
operation of these functional modules is explained in more detail below.
The principle of the ranging procedure is that a terminal station after
becoming active, e.g. TSi, sends upon receipt of a start ranging signal
called start CR, a ranging signal towards CS. Depending on the type of the
network, this signal is either sent out at an amplitude relatively smaller
than that of the information signals included in the PON upstream cells or
at an amplitude in the range thereof. In relatively small networks, where
there is no need for optical amplifiers, the ranging signal is sent out at
the relatively lower amplitude, which is such that there is no degradation
of the information signals. However in larger networks including optical
amplifiers, the resulting noise signal can have an amplitude in the range
of the lower amplitude ranging signal, and therefore, the ranging signal
is then generated at an amplitude in the range of the PON cell signals. In
order to be able to recover the latter signals in case of possible
degradation due to the transmission of the ranging signal, Forward Error
Correction coding such as the Reed Solomon coding, is included in the
cells. Use of such error codes in transmission systems is well known in
the art and is therefore not described in details.
A predetermined period after the sending of the start CR signal, CS sends a
inhibit signal to the other terminal stations to stop sending cells during
a well defined time interval, also called ranging window, which is smaller
than the time interval during which the ranging signal is transmitted by
TSi. Upon receipt of the ranging signal during the ranging window, CS
determines based on the contents of the signal, a first evaluation of the
transmission delay of TSi, as will be described hereafter, and transmits
the thus obtained evaluation of the transmission delay to TSi. The ranging
procedure is possibly repeated a predetermined number of times to more
accurately evaluate this transmission delay. However, during those
repetitions, the ranging signal is not sent out upon receipt of the start
CR signal but a predetermined time interval thereafter. This time interval
equals a ranging delay deduced from the previously evaluated transmission
delay. As will be explained hereafter, the ranging signal, which consists
of a number of repeated sequence numbers contained in this signal, is
adapted accordingly. The complete procedure is additionally repeated on a
periodic basis while TSi is active, to possibly adjust the determined
transmission delay. In order to clarify how the value of the parameters
used in the ranging procedure such as the time interval between the
sending of the start CR and the signal to inhibit the sending of cells and
the type of ranging signal are chosen, a description is given hereafter of
a ranging procedure applied to a specific example to which FIG. 2 is
applicable.
A network of maximum length of 4 cells is considered.
As already mentioned earlier, the ranging signal consists of subsequently
sent ranging messages. These messages are sent with a cell frequency and
include subsequent sequence numbers. For a network with a maximum length
of 4 cells and choosing a maximum sequence number of 2, the ranging window
has at least to be opened during the 8th cell after the transmission of
the start CR signal to take into account a possible location of a terminal
station performing the ranging procedure at the maximum distance from the
central station. However, in order to see at the central station possible
sequence transitions, a window of 2 cells, i.e. the 8th and the 9th cell
after the start CR, is opened. As a result, the ranging signal has to
consist initially in a first execution of the steps of the method of 8
ranging messages, 4 with sequence number 1 and 4 with sequence number 2,
to take into account a possible location of the terminal station at a
minimum distance from the central station. In this example the ranging
procedure is performed by a terminal station TS located within the first
cell from the central station. This means, as can be seen in FIG. 2a, that
the terminal station receives the start CR after an interval smaller than
1 cell and that the ranging signal, or more specifically the first message
thereof is received by the central station between 1 and 2 cells after the
latter starts the CR signal. As a result, the central station sees in the
ranging window 2 times a sequence number 2, from which it can be deduced
that the terminal station is located in the first half of the network,
i.e. between 0 and 2 cells away from that central station.
This is communicated to the terminal station, which in a second step, i.e.
after receipt of a second start CR signal, supposes it is located 2 cells
away from the central station and waits for its first evaluated ranging
delay of 2.times.(4-2)=4 cells before transmitting the ranging signal.
This ranging signal then consists of the sending of 4 ranging messages, 2
with sequence number 1 and 2 with sequence number 2. The open window again
includes the 8th and 9th cell after the start CR and as a result, the
central station again sees 2 times the sequence number 2 as can be seen in
FIG. 2b, meaning that the terminal station is located within the first
half of the first half of the network, i.e. within 1 cell from the central
station. In this way, the transmission delay of the station is determined
with an accuracy of 1 cell.
It should be noted that had the terminal station been located in the second
part of the network, then it would have supposed to be located 4 cells
away from the central station and it would, in a second step of the
ranging, have sent out a ranging signal immediately after the receipt of
the start CR.
Generalizing the above description, the parameters for the subject ranging
method can be defined as follows.
Assuming that L is the number of upstream cells corresponding to twice the
maximum difference in transmission delay between two terminal stations,
i.e. twice the maximal distance between the central station and a terminal
station, and 2" being the maximum sequence number, then a terminal station
has to send after the first start CR:
m times the sequence number 1;
. . ;
m times the sequence number 2" where m=L/2".
The central station opens a ranging window of 2 cells during the Lth and
the L+1th cell. The sequence number read in this window gives the
transmission delay with an accuracy of L/2", As such, the measurement must
be repeated L/2" times, with m being in the subsequent steps divided by 2,
in order to determine the transmission delay with a cell accuracy.
It should be noted that the maximum sequence number can be chosen in
different ways. The higher this maximum number the more accurately the
ranging delay can be determined, but the longer the ranging signal becomes
since then more bits are needed to specify the sequence numbers.
In an alternative method, instead of waiting for a time interval equal to a
coarse ranging delay, when the latter is known, the ranging signal can in
the repetitions of the steps as described above be sent out immediately
after the receipt of the start CR, and the central station can rely upon
the fact that no ranging message is received in at least part of the
ranging window to more accurately determine the transmission delay.
It should also be noted that in order to be able to perform the above
described ranging method, the terminal station as well as the central
station have to be aware of the value of L and of the chosen maximum
sequence number, which have thus to be preconfigured in these latter
stations.
Since it will be apparent for a person skilled in the art how to implement
a central station and a terminal station based on the above functional
description of the steps to be performed to realize the subject ranging
procedure, and based of the already known implementations of central
stations and terminal stations, these stations are not described herein in
further detail.
While the principles of the invention have been described above in
connection with specific apparatus, it is to be clearly understood that
this description is made only by way of example and not as a limitation on
the scope of the invention.
* * * * *
![[Image]](/netaicon/PTO/image.gif)
![[Home]](/netaicon/PTO/home.gif)
![[Boolean Search]](/netaicon/PTO/boolean.gif)
![[Manual Search]](/netaicon/PTO/manual.gif)
![[Number Search]](/netaicon/PTO/number.gif)
![[Help]](/netaicon/PTO/help.gif)
![[Bottom]](/netaicon/PTO/bottom.gif)
![[View Shopping Cart]](/netaicon/PTO/cart.gif)
![[Add to Shopping Cart]](/netaicon/PTO/order.gif)
![[Top]](/netaicon/PTO/top.gif)