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Claims  |
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I claim:
1. In a stored program control (SPC) switched communications network
including multiple SPC switch means connected by trunk means for
establishing communication paths between said switch means, and including
common channel signal (CCS) links connecting each of said switch means to
interface means at each of two signal transfer points (STPs), the method
comprising:
(a) providing dual input analyzer and control (DIAC) means at each of said
two STPs;
(b) providing control communication link means and data communication link
means between said two STPs;
(c) connecting an input of said DIAC means at a first STP to a CCS
interface means at said first STP connected to a selected switch means to
permit monitoring a first signal at said CCS interface means by said DIAC
means at said first STP;
(d) accessing the DIAC means at the second of said STPs from the DIAC means
at said first STP via said control communication link means;
(e) using said DIAC at said first STP and said control communication link
means to cause said DIAC means at said second STP to connect to the CCS
link between said second STP and said selected switch means via said data
communication link means between said DIAC means to permit monitoring of a
second signal on said CCS link connecting said second STP to said selected
switch means for simultaneous monitoring of at least said first and second
signals on said two CCS links connecting said selected switch means to
said first and second STP.
2. A method according to claim 1 including the step of accessing the DIAC
means at the second of said STPs from the DIAC means at said first STP via
a dialup communications link.
3. A method according to claim 1 wherein steps (c), (d) and (e) are
initiated from a site remote from said STP means.
4. A method according to claim 1 including the step of initiating (c), (d)
and (e) from a PC means remote from said STPs and connected to said DIAC
means at said STP via a dial-up link means.
5. In a stored program control (SPC) switched communications network
including multiple SPC switch means connected by trunk means for
establishing communication paths between said switch means, and including
common channel signal (CCS) links connecting each of said switch means to
interface means at each of two signal transfer points (STPs), the method
comprising:
(a) providing dual input analyzer and control (DIAC) means at each of said
two STPs;
(b) providing a dial-up communication link between said two STPs;
(c) providing a data communication link means between said two STPs;
(d) connecting an input of said DIAC means at a first STP to a CCS
interface means at said first STP connected to a selected switch means to
permit monitoring of a first signal at said CCS interface means by said
DIAC means at said first STP;
(e) accessing the DIAC means at the second of said STPs from the DIAC means
at said first STP via said dial-up communication link;
(f) using said DIAC means at said first STP and dial-up communication link
to cause said DIAC means at said second STP to connect to the CCS link
between said second STP and said selected switch means via said data
communication link means between said two STPs to permit monitoring of a
second signal on the CCS link connecting said second STP to said selected
switch means for simultaneous monitoring of at least said first and second
signals on said two CCS links connecting said selected switch means to
said first and second STPs;
(g) monitoring at said DIAC means CCS signals on said CCS links; and
(h) initiating steps (d), (e), (f) and (g) from a site remote from said STP
means.
6. In a stored program control (SPC) switched communications network
including multiple SPC switch means connected by trunk means for
establishing communication paths between said switch means, and including
common channel signal (CCS) links connecting each of said switch means to
interface means at each of two signal transfer points (STPs), the method
at each of two signal transfer points (STPs), the method comprising:
(a) providing analyzer and control (AAC) means at each of said STPs, at
least one of the AAC means being a dual input AAC (DI/AAC) means;
(b) providing multiple communication link means between said two STPs;
(c) connecting an input of said DI/AAC means at a first STP to the
interface means at said STP for the CCS link to a selected switch means to
permit monitoring of signals at said CCS interface by said DI/AAC means;
(d) accessing the AAC means at a second of said STPs from the DI/AAC means
at said first STP via a selected one of said communication link means;
(e) signaling said AAC means at the second STP from said DI/AAC means at
said first STP via said selected one of said communication link means to
cause said AAC means to effect connection of the CCS interface means at
said second STP connected to said selected switch means to said
communication link means to establish a connection to an input of said
DI/AAC means to permit monitoring of CCS signals on both of said CCS links
to said selected switch means by said DI/AAC means.
7. A method according to claim 6 including the step of simultaneously
monitoring on said DI/AAC means CCS signals on said CCS links.
8. A method according to claim 6 including the step of accessing the AAC
means on a dial-up communication link means.
9. A method according to claim 6 wherein said AAC means is accessed and
signaled via one communication link means and the CCS interface means at
said second STP is connected to another communication link means.
10. A method according to claim 6 wherein both said AAC means are DI/AAC
means to permit monitoring of CCS signals on said CCS links by either of
said DI/AAC means.
11. A method according to claim 6 wherein steps (c), (d) and (e) are
initiated from a site remote from said STPs.
12. A method according to claim 6 wherein steps (c), (d) and (e) are
initiated from PC means located remotely from said STPs and connected to
said DI/AAC means via a dial-up communications link.
13. In a stored program control (SPC) switched communications network
including multiple SPC switch means connected by trunk means for
establishing communication paths between said switch means, and including
common channel signal (CCS) links connecting each of said switch means to
interface means at each of two signal transfer points (STPs), the
improvement comprising:
analyzer and control means associated with each of said STPs;
control communication link means between said STPs for connecting said
analyzer and control means to one another;
data communication link means connecting said STPs;
at least one of said analyzer and control means having dual input means and
being program controlled to connect an input of said analyzer and control
means to a CCS interface means at the STP with which said analyzer and
control means is associated to connect said input of said analyzer and
control means to a selected switch means via a CCS link between said
interface means and said switch means to permit said dual input analyzer
and control means to monitor a signal on said CCS interface means at said
STP;
said dual input program controlled analyzer and control means being
connected to the analyzer and control means at the other of said STPs via
said control communication link means;
said other analyzer and control means under control of said dual input
program controlled analyzer and control means establishing at the STP
associated with said other analyzer and control means a connection between
said data communication link means and a CCS interface means at said other
STP, which interface means is connected to a CCS link between said other
STP and said selected switch means;
said data communication link means being connected at said first STP to an
input means of said dual input means program controlled analyzer and
control means whereby said dual input program controlled analyzer and
control means is simultaneously connected via two CCS links to said
selected switch means.
14. An SPC switched communications network according to claim 15 including
computer control means remote from said STPs connected to said dual input
program controlled analyzer and control means to control the actions of
said dual input program controlled analyzer and control means responsive
to said program.
15. In a stored program control (SPC) switched communications network
including multiple SPC switch means connected by trunk means for
establishing communication paths between said switch means, and including
common channel signal (CCS) links connecting each of said switch means to
interface means at each of two signal transfer points (STPs), the
improvement comprising:
analyzer and control (AAC) means associated with each of said STPs, at
least one of said AAC means being a dual input AAC (DI/AAC) means;
multiple communication link means between said two STPs;
said DI/AAC means being program controlled to connect an input of said
DI/AAC means to a CCS interface means at the STP with which said DI/AAC
means is associated to connect said input of said Di/AAC means to a
selected switch means via a CCS link between said interface means and said
switch means to permit said DI/AAC means to monitor a signal on said CCS
interface means at said STP;
said DI/AAC means being connected to the AAC means at the other of said
STPs via a selected one of said communication link means;
said AAC means under control of said DI/AAC means establishing at the STP
associated with said AAC means a connection between said selected one of
said communication link means and a CCS interface means at said other STP,
which interface means is connected to a CCS link between said other STP
and said selected switch means;
said selected one of said communication link means being connected at said
first STP to an input means of said DI/AAC means whereby said DI/AAC means
is simultaneously connected via two CCS links to said selected switch
means.
16. A SPC switched communication network according to claim 15 wherein said
DI/AAC means is connected to said AAC means via a dial-up communication
link means to control said AAC means to establish a connection between
said CCS interface means at said other STP is effected via a distinct
communication link means.
17. In a stored program control (SPC) switched communications network
including multiple SPC switch means connected by trunk means for
establishing communication paths between said switch means, and including
common channel signal (CCS) links connecting each of said switch means to
interface means at each of two signal transfer points (STPs), the
improvement comprising:
program controlled dual input analyzer and control means associated with
each of said STPs;
dial-up communication link means between said STPs for connecting said
analyzer and control means to one another;
data communication link means connecting said STPs;
means at a first of said analyzer and control means to cause connection of
an input of said analyzer and control means to a CCS interface means at
the STP with which said first analyzer and control means is associated to
connect said input of said first analyzer and control means to a selected
switch means via a CCS link between said interface means and said switch
means to permit said first analyzer and control means to monitor a signal
on said CCS interface means at said STP;
means at said first analyzer and control means to cause connection of said
first analyzer and control means to the second of said analyzer and
control means at the other of said STPs via said dial-up communication
link means;
means at said first analyzer and control means to cause at the STP
associated with said second analyzer and control means a connection
between said data communication link means and a CCS interface means at
said other STP, which interface means is connected to a CCS link between
said other STP and said selected switch means:
means at said first analyzer and control means to cause said data
communication link means to be connected at said first STP to the other of
said input means of said dual input analyzer and control means so that
said first analyzer and control means is simultaneously connected via two
CCS links to said selected switch means;
and a dial-up communication link means connected to said first analyzer and
control means and a station remote therefrom, said first analyzer and
control means being controlled from said remote location. |
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Claims |
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Description |
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CROSS REFERENCES TO RELATED APPLICATIONS
This application is related to co-pending applications Ser. Nos. 07/515,007
filed Apr. 26 1990; 07/646,319 filed Jan. 28, 1991 07/911,642 filed Jul.
10, 1992 and U.S. Pat. No. 4,998,240 issued Mar. 5, 1991, all commonly
assigned with the present invention.
TECHNICAL FIELD
The present invention relates generally to remote testing of a plurality of
telecommunications and the like data transfer communications lines, and
more particularly to the remote and unattended protocol analysis of Common
Channel Signaling (CCS) lines using Signaling System 7 (SS7) Protocol.
BACKGROUND ART
Assignee's U.S. Pat. No. 4,998,240 describes a method and apparatus for
remote and unattended testing of customer ISDN lines at an unmanned
central office using conventional protocol analyzer equipment. Related
patent application Ser. No. 07/646,319 filed Jan. 28, 1991, describes a
system and method for remotely testing a plurality of private data network
communication lines using a conventional protocol analyzer. Two
commercially available protocol analyzers for these purposes are the Bell
Atlantic Remote ISDN Protocol Analyzer and the Bell Atlantic Test Systems
( BATS ) Network Analyzer. These are program controlled analyzers. Related
Application Ser. No. 07/911,642, filed Jul. 10, 1992, describes a control
and port selection arrangement which may be utilized with the BATS
protocol analyzers to effect program controlled port selection and control
functions is described in that application.
The present invention deals with the testing, monitoring and analyzing of
control signaling in Stored Program Control (SPC) switched telephone, data
and the like networks. Traditional control signaling in such networks,
particularly SPC switched telephone networks has been on a per-trunk or in
channel basis. With in channel signaling the same channel is used to carry
control signals as is used to carry the call to which the control signals
relate. Such signaling begins an the originating subscriber and follows
the same path as the call itself.
In current telecommunications and data networks such in-channel signaling
is being replaced with Common Channel Signaling (CCS) in which control
signals are carried over paths completely independent of the voice
channels. The common channel can be configured with the bandwidth required
to carry control signals for a large variety of functions. Thus both the
signaling protocol and the network architectures to support that protocol
are more complex than in channel signaling.
CCS provides a method for exchanging information between Stored Program
Control Systems (SPCs) that are inter-connected through a network of
signaling links. CCS network nodes may include but are not limited to
switching systems, network databases and operator service systems. The
current common protocol for CCS is Specification of Signaling System 7
(SS7) which is described in Section 6.5, LSSGR, Issue 2, Jul. 1987,
TR-TSY-000506, a module of TR-TSY-000064.
Referring to FIG. 1 there is shown a simplified diagram of an SPC telephone
network linking individual subscribers through Central Offices (COs) which
are connected by trunks and linked by a typical CCS network. The COs
typically consist of a programmable digital switch with CCIS
communications capabilities such as an AT&T 5ESS or Northern Telecom
DS-100 or the like and may or may not be equipped and programmed to serve
as Service Switching Points (SSPs). In FIG. 1 series of central office
switches 10, 12 and 14 are shown connected to groups of local subscribers
16, 18 and 20 by conventional local loops or subscriber lines. The COs 10,
12 and 14 are connected by trunk circuits 22 and 24, by way of example.
Common Channel Signaling is provided by SS7 data links 26-36 extending
between each CO and Signaling Transfer Points (STPs) 38 and 40. These
local STPs may be connected to state or regional STPs, not shown.
A pair of STPs is conventionally provided per LATA to provide redundancy so
that in the event of failure of one the other immediately assumes its
load. Similarly, if one STP becomes overloaded the other shares the load
to create a load balance. The paired STPs are connected by C-links so that
each STP understands what the other is doing at all times. The STPs may be
configured to continually share the load or may be configured in a hot and
stand-by capacity. Generally speaking, one will basically monitor the
other while they share the load. If one goes down the other is immediately
aware of the situation via the C-link and picks up the load to avoid an
outage.
Thus each of the COs 10, 12 and 14 are connected to each of the STPs 38 and
40. The STPs provide call processing data transfer between the various COs
in the normal manner of SS7 common channel signaling.
In current usage of a CCS network of the type shown in FIG. 1, testing of
the CCS or SS7 functioning must be carried out at the particular central
office under surveillance in order to permit viewing both of the
associated SS7 links at the same time, which is necessary to an effective
test. This is ordinarily accomplished using a portable analyzer physically
carried to the CO by maintenance personnel. It is only at this CO that the
two SS7 links are physically accessible. However, that central office may
be many miles distant so that the test may be not only delayed but also
highly wasteful of personnel time. In addition, the results of on-site
monitoring and collection of data often require more detailed analysis at
the maintenance facility. Conveyance of such information to the facility
in a timely manner may be costly and inconvenient and yet another trip to
the malfunctioning CO may be required.
These problems and disadvantages are multiplied when a central office
exhibits a recurring problem that requires extended attention. For
example, in a case of network administration, a malfunction may be
observed to occur frequently at the same time of day. To diagnose this a
technician would have to personally attend the local site each day at the
same time until the problem is diagnosed or, alternatively, remain at the
site during the entire time of test. As an operating technician is
required to be at the testing site, cost considerations restrict use to
short, noncontinuous periods. Testing is normally done either on a routine
basis or after identification of the existence of a problem whose exact
nature is not yet known. Conventional protocol analysis is therefore
limited in that it cannot practically be used to monitor the data stream
of a selected circuit continuously over an extended period of time. In the
absence of such extended monitoring there is no pragmatic way to detect
the occurrence of a predefined condition and to initiate a control
function upon recognition of such occurrence.
OBJECTS OF THE INVENTION
It is an object of the present invention to provide a system and method for
effecting efficient and economical protocol and network analysis of common
channel signaling links from a remote location.
Another object of the invention is to designate from a remote location one
of a plurality of common channel signaling links to be accessed for
protocol analysis.
Another object of the invention is to perform protocol analysis of common
channel signaling links without requiring the presence of an operating
technician at the analysis site.
Another object of the invention is to provide nonintrusive, continuous
monitoring and storage of analysis data with the ability to automatically
transmit the data to a specified remote location at specified times.
Yet another object of the invention is to provide the ability to define,
from a remote location, a network transmission condition, the occurrence
of which will be automatically detected, and in response to such
detection, to automatically initiate a control function.
DISCLOSURE OF THE INVENTION
The above and other objects of the invention are satisfied, at least in
part, by remotely testing dual CCS or SS7 access links simultaneously from
a single transfer point on the CCS or SS7 network. In accordance with one
feature of the invention a dual port protocol analyzer is situated at the
site of each of two paired STPs for operation in a master and slave
analyzer module capacity. These paired STPs may be referred to as STP A
and STP B. A port selector associated with each dual port protocol
analyzer has the port connections thereof connected to the STP interface
with incoming/outgoing SS7 links.
A simultaneous test of paired SS7 links or lines is then performed from the
control or master analyzer module at STP A by commanding the system to
select the port or SS7 interface at STP A which is linked to the central
office under test. This interface port is connected by the port connector
of the protocol analyzer to one of the dual inputs of the analyzer to
decode and display on that analyzer the SS7 data associated with the
central office under test. The information may be outputted by the
analyzer on a monitor or printer and may be recorded on a hard disc or
other storage medium for later accessing.
However this constitutes only one half of the needed information. In order
to obtain the other half the control module associated with the master
protocol analyzer and control unit at STP A accesses the control module
associated with the slave protocol analyzer and control unit located in
the paired STP B. This access may be by any available connection such as a
2400 BAUD dial-up control link.
After this dial-up link is established the control module in the master
analyzer and control unit at STP A commands the control module in the
slave protocol analyzer and control unit at STP B to connect the CCS or
SS7 link at STP B that is paired with the selected SS7 link and access
port at STP A to dedicated DSO T1 carrier channels between STP A and STP
B. The STP A end of these DSO channels terminates in the selected SS7
access port or interface at STP A which is connected to the other input
port of the master dual port protocol analyzer and controller. This places
the SS7 or other CCS control data from the central office under
observation at both input ports of the master dual port protocol analyzer
at STP A so that protocol monitoring may occur on both of the paired CCS
or SS7 links of the CO under test from a centralized location, namely STP
A.
This testing arrangement can be controlled in the local mode by personnel
located at STP A where the master analyzer and control module is situated.
Alternatively or the process may be reversed and the slave unit in STP B
can become the master control unit and to provide diagnostics at that
analyzer and STP. It is another feature of the invention that in the case
no personnel are located in either STP both units can be remotely
controlled from a centralized location via dial-up DDD access or by
dedicated data circuit access. The monitor access points can be configured
to provide V.35 or T1 carrier access at the STP.
Additional objects and advantages of the present invention will become
readily apparent to those skilled in this art from the following detailed
description, wherein only the preferred embodiment of the invention is
shown and described, simply by way of illustration of the best mode
contemplated of carrying out the invention. As will be realized, the
invention is capable of other and different embodiments, and its several
details are capable of modifications in various obvious respects, all
without departing from the invention. Accordingly, the drawings and
description are to be regarded as illustrative in nature, and not as
restrictive.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a diagrammatic illustration of a conventional stored program
controlled (SPC) switched telephone network using SS7 protocol common
channel signaling with paired signal transfer points (STPs).
FIG. 2 is a simplified diagrammatic illustration of the network of FIG. 1
supplied with dual port protocol analyzers and control units at the STPs
and disposed to effect monitoring and testing according to the preferred
embodiment of the invention.
FIG. 3 is a reproduction of the arrangement illustrated in FIG. 2 showing
the connection effected by operator selection of port Number 1 as an
initial step to testing the functioning of the SS7 link to central office
Number 1.
FIG. 4 is a reproduction of the arrangement illustrated in FIG. 2 showing
the flow of test data from port Number 1 to the master protocol analyzer
following the connection illustrated in FIG. 3.
FIG. 5 is a reproduction of the arrangement illustrated in FIG. 2 showing
the control module of the master analyzer accessing the slave protocol
analyzer and port selector via a dial-up control link.
FIG. 6 is a reproduction of the arrangement illustrated in FIG. 2 showing
the connection of the SS7 link from port Number 1 of STP B to the master
protocol analyzer in STP A to provide an SS7 output on the second port of
the dual port analyzer at STP A.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to FIG. 2 there are shown three central offices Numbers 1, 2 and
3 corresponding to COs 10, 12 and 14 in FIG. 1. COs 1, 2 and 3 in FIG. 2
bear like reference numerals as in FIG. 1. The STPs 38 and 40 of FIG. 1
are shown as STP A and STP B respectively in FIG. 2. The STPs A and B are
connected to the COs Numbers 1-3 by SS7 links 26-36 as in FIG. 1. At each
of the STPs A and B there is provided a BATS dual port network analyzer.
Each analyzer comprises a control module 42, 44 having associated monitors
and keyboards 46, 48 and port selectors 50, 52. The control modules 42 and
44 each include a CPU and other PC components and also include a port
selector and control circuit board of the type described in the common
assignee's co-pending application Ser. No. 07/911,642 filed Jul. 10, 1992.
That application is incorporated herein by reference. The port selector
and control circuit board controls the port selector 50, 52.
This control board in conjunction with the port selector allows for the
operate/non-operate control of up to 180 port relays in the port selectors
50 and 52 along with 8 switching control functions per board. While the
port selectors shown in the drawings illustrate 24 port selections, it
will be understood that this is by way of illustration only and that the
port selector modules 50 and 52 may be stacked to provide up to 180 port
relays per control board in the analyzer. Multiple control boards are
usable with each analyzer so that the number of ports which may be
accessed and/or controlled is very large.
The port selector and control board is controlled by software running under
standard PC DOS or MS DOS as described in the said co-pending application.
The control and selector board may be controlled completely from the
keyboards 46 and 48, or through the use of commercially available
software, such as PC Anywhere, the control and selection board can be
controlled from a remote IBM or IBM-compatible computer.
The selector and control board is switch address selectable, allowing for
the use of multiple control boards in the same IBM or IBM compatible
computer. The maximum number of control boards that can be used in one IBM
or IBM compatible computer depends upon the number of free expansion slots
available in the computer and the number of available expansion slot
addresses. In general it is possible to be able to use 4 to 5 such control
boards in any IBM or IBM compatible computer, allowing for the control of
up to 900 or more port relays and up to 40 simultaneous circuit control
outputs.
The hardware design of the selector and control board allows for the 8
simultaneous circuit control outputs to be controlled by the software in
any combination of outputs 0 through 7 (8 outputs), at a time or any
combination of the 8, including all 8 at one time. The outputs latch to
the desired state and will remain in that state until changed by the
software or reset by the control output reset (resets all 8 control
outputs to logic 0) or by the master selector board reset (resets all
board outputs to logic 0).
The software normally allows for only one of the 180 port relay control
outputs to be selected at a time. However in modified form the hardware
design allows the software to select one port relay control. output for
every 15 outputs. Therefore, up to 12 port relay control outputs may be
controlled at the same time. The hardware design also allows each
individual group of 15 port relay control outputs to be converted
individually to 4 simultaneous circuit control outputs by unplugging one
integrated circuit and plugging in a customer integrated circuit module in
its place. In this situation, 15 port relay control outputs are sacrificed
to gain 4 simultaneous circuit control outputs. A wide range of
flexibility is thus provided.
The control unit 42 may also be connected via a modem 56 to telephone line
access which is diagrammatically illustrated as a J11 jack 58. Remote
control as well as remote read-out may be effected via this access. A
similar modem and jack connection 60 and 62 are provided for the analyzer
at STP B. The control units 42 and 44 also include facsimile output
capability whereby data can be transmitted to remote facsimile machines 64
and 66 through telephone access lines indicated diagrammatically by J11
acks 68 and 70.
It is a feature of the invention that the system system illustrated in FIG.
2 may be used to simultaneously remotely access both SS7 Access links
(A-links) that are routed to separate signal transfer points (STPs). This
is done at an STP in a manner that allows the viewing of the SS7 or other
CCS signaling data on both SS7 A-links at the same time. This is necessary
in diagnostic work due to the fact that both the primary STP and the
secondary STP may be involved in the handling of a single call. At the
time that the analyzers are installed at the STPs it is necessary to
connect the pertinent relay terminals in the port selectors 50, 52 to the
various STP SS7 link interface ports 1-24 in FIG. 2. While only three
central offices are illustrated it will be understood that a larger number
are customarily handled by paired STPs. After the initial installation the
test system is completely transparent and is non-intrusive during use.
According to the invention the system of FIG. 2 including the analyzers at
STPs 38 and 40, STP A and STP B, may be used as follows:
The operator or technician at STP A commands the dual port protocol
analyzer in STP A, including control module 42 and port selector 50, to
select interface or port Number 1 which is connected to central office
Number 1 as the central office selected for test in this illustrative
example. This connection is indicated at 54 in FIG. 3. Port Number 1 and
the SS7 A-link 26 are thus connected from central office Number 1 through
the STP A port selector 50 and control module 42 to the monitor 46 for
observation and monitoring. This path is illustrated graphically at 72 in
FIG. 4. The operator may then observe the decoded display which represents
the signal on SS7 A-link 26.
Having made this connection the control module 42 in STP A accesses the
slave control module 44 in STP B via a telephone link such as the 2400
BAUD dial-up link 74. This connection is indicated by the broken line 76
in FIG. 5.
After the dial-up control link is established the control module 42 in STP
A commands the control module 44 in STP B to establish a bridging
connection between the A-link 32 connected to port Number 1 in STP B and
an available data communication link between the two port selectors 50 and
52, such as two DSO channels from a T1 link 78. These two DSO channels
would preferably be a dedicated circuit.
This creates a loop connection which is indicated at 80 in FIG. 6. The end
of the 2 DSO channels terminating at STP A is connected via the master
port selector 50 and master control unit 42 for decoding and display on
the master monitor 46 at STP A. This simultaneously places the SS7 control
data from central office Number 1 from both A-links at the two sets of
terminals of the master dual port protocol analyzer an STP A so that
monitoring may be accomplished on both A-links from a centralized
location, namely the site of STP A and its analyzer.
This testing arrangement can be controlled in the local mode by personnel
located in STP A or the process can be reversed and the slave unit in STP
B can become the master control unit and allow diagnostics from STP B. In
the case that no personnel are located in either STP A or STP B both units
can be remotely controlled from a centralized location via dial-up DDD
access or by dedicated circuit access.
The monitor access points can be configured to provide V.35 or T1 carrier
access at the signal transfer point.
It will be apparent from the foregoing that the present invention provides
a system and method for effecting efficient and economical protocol and
network analysis of common channel signaling links from a remote location.
The necessity for an operating technician at the analysis site is
completely obviated. The invention provides a non-intrusive, continuous
monitoring and storage of analysis data with the ability to automatically
transmit the data to a specified remote location at specified times if
desired. The remotely controlled testing may be effectuated using
available equipment and telecommunication and data network links. Once
installed the system and its operation are totally transparent to the
network users.
It will be readily seen by one of ordinary skill in the art that the
present invention fulfills all of the objects set forth above. After
reading the foregoing specification, one of ordinary skill will be able to
effect various changes, substitutions of equivalents and various other
aspects of the invention as broadly disclosed herein. It is therefore
intended that the protection granted hereon be limited only by the
definition contained in the appended claims and equivalents thereof.
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