NO309839B1 - Set up of telemetry connections in communication networks - Google Patents

Description

This invention relates to telemetry systems that use connection networks, and more specifically, the invention relates to devices for setting up or initiating telemetry connections from remote stations in such systems.

Today there are many applications where equipment at the customer's or subscriber's location, since the customer or subscriber can be considered an end user of telemetry services, activates a telemetry connection from a remote location to some central service station. Such conditions apply, e.g. transmission of an instrument reading, a counter step registration, reporting of energy and equipment use, alarm or maintenance situations or transmission of burglary or fire alarm signals from homes and to service agencies, possibly directly to the police or fire brigade. In such systems, a call will be set up directly to the service point when an alarm indication is registered, and some notification or identification of the person making the call will also be transmitted in connection to the service point or the aid station. The station responds by sending the police or fire brigade to the place from which the alarm signal was sent. Telemetry calls can also be set up from remote locations to transmit a "data report" or fault situation message. In the description that applies here, it is assumed that calls that are set up from equipment on the subscriber's or customer's side are said to be "incoming" (i.e. that the call arrives at a switching station or a service point), while calls that originate in this station or this location is said to be "outgoing".

A problem with such facilities is that a data stream (a sequence of digital signals or signals containing information relating to technical data) from the caller to the point of service may be weakened, disturbed or interrupted by signals such as automatic call alert signals in a switching system if the transmitting subscriber the alarm signal has such an automatic call notification option and if another subscriber accidentally initiates a call during the telemetry connection. The use of such equipment further limits the subscriber's ability to connect to telephone selection or shielding systems such as services that allow the subscriber to be barred from connection with remote subscribers within a certain area should the service point happen to be in such an area, in A problem encountered within telecommunications technology is thus that there can be significant interference between a large category of modern telecommunications services and remotely activated telemetry reporting services or alarm services.

However, this particular problem has been solved, and a step has been taken further with the present invention which dictates that a special service call such as a telemetry call is identified by means of an access code, after which the reception of the same code causes the switching or switching of the system to special functions inactive for the caller, e.g. to block incoming calls or messages that are waiting as long as the special service call is taking place and at the same time deactivating the outgoing call barring. In a particular embodiment of the invention, the switching system further checks whether a call or a call following the access code is restricted to calls to predetermined telephone numbers. After disconnecting the special service function, the subscriber's special services will be activated again, including automatic call notification if this function is relevant. Preferably, such a device will break any connection between the subscriber functions and the characteristic parameters of a remote telemetry connection to a service or assistance location and does so at a low cost by providing a simple set of programmed controls, feature deactivation and reactivation in a remote connection switching system that is coupled to the call line for the remote telemetry transmission.

In accordance with one aspect of the preferred embodiment of the invention, the call or transfer is billed to the called subscriber. Subscribers often choose such an arrangement since the telemetry transmission is considered to be part of the auxiliary or alarm monitoring service and so that one does not really want to pay for services that are not used. The device also allows connections to originate from lines that are blocked in most types of dispatch locations, e.g. from home where no one is present.

According to a preferred embodiment of the invention, the standardized call billing circuit used for remote reading of counter steps and monitoring of communication equipment is preferably used to allow incoming call control. The pedometer that has been devised disconnects from the telephone when the incoming call is of an emergency nature, from a device such as an alarm or a medical monitoring station, precisely because of the higher priority of the emergency signals. Preferably, the additional costs for providing telemetry services in the form of a remote connection are reduced in this way.

According to a particular embodiment of the invention, a special indicator in the setup call can perform the same function as that performed by the access code in a connection of the type conventional analog line connection, if the telephone instrument on the line used for combined telephony and telemetry connection belongs to a telephone service of type (ISDN) (integrated digital service network). The network's D channel is used for connection between the connected switching system and the customer's or subscriber's telemetry equipment. With this type of device, it will not be necessary to disconnect the end user's telephone equipment during the telemetry connection.

The aspects and embodiments of the invention that are discussed above are specified in more detail in the patent claims on pages 11 and 12, the first of which specifically states the invention's method for establishing a special] single call to a destination in a connection switching system for operating one line and several other lines, which method is characterized by: Deactivation of a class of subscriber functions for the line, which class of functions is identified by an identification indicator that is included in the special service call, while the class of functions further includes functions that may interfere with the special service call, the connection switching system having a response to receiving a special service calls from the line, and automatic deactivation of the functions that may interfere with the special service call when it is on its way to the destination in the connection switching system, as this has a response to the special service call during its way to the destination.

Fig. 1 shows a block diagram of the connections for transferring data from subscribers' instruments, counters and devices, and Fig. 2-3 show flowcharts for the activities carried out when setting up connections from such devices.

The telemetry service described here for incoming calls for utility services (Telemetry Interface Unit to Utility) is based on an outgoing utility service within the same type of telemetry transmission (Utility to Telemetry Interface Unit). A station service center (COSU) - (Central Office Service Unit) can serve several stations with standardized analog or digital E & M interstation line groups. The COSU is connected to the utility (Utility) or a service subcontractor via a dial-up line, a private telephone line or via a "packet network".

The following "incoming" subscriber service will be reviewed in connection with an instrumentation, meter reading or call billing service. The structure of the network and details of the switching or switching may also apply to other applications such as fire alarm, security guard service and installation-activated services.

Using today's known technique for processing incoming calls or messages, a communication circuit MICC (Meter Interface Communications Circuit) in the form of a transition between a counter circuit for call charging and the system (Fig. 1, block 46) performs direct dialing by means of a switching center dialing mechanism or switch 21 and to an auxiliary station for the relevant service or to a service provider in the form of a subcontractor. There is no control of the functions linked to the call line. Call features such as automatic call notification can interrupt the data stream and cause errors or completely destroy the call. Call barring lists can prevent the MICC from logging the call. This disruption causes time-consuming further retransmissions, reactivated incoming telemetry calls and lack of opportunities to transfer messages. If the telemetry call is allowed to proceed, the MICC can initiate switches available to the end users, e.g. an automatic call notification can be activated, but other end-user functions on the same line will not be able to be prevented, since the end-users have no direct "suspension control" for these functions.

In accordance with the invention, the telemetry unit will be able to route the call from the end user's line to a station service center 20 which then sets up a connection with an auxiliary service or a function within a service location 60. This selector mechanism recognizes the telemetry call based on an access code, and a second dial tone is presented for the destination area code. The selector mechanism then disables the end-user's line features for the telemetry calls and re-enables the end-user's line features at the end of the call, i.e. when the message is finished. At this point, an automatic message account (AMA) is issued, whereby the service use is charged to the issuer

(return load). Since such calls just have a return charge, incoming telemetry calls can be allowed from lines that are not assigned to any payment (unoccupied buildings etc).

Calls to the point of use of the service from the relevant central service point can be made via a circuit switching network, a packet network or routed via a selector mechanism of category MHG (multiline paging groups) or ACD (an automatic call distributor).

The MICC disconnects and enters an access code. The switch recognizes this access code and gives a second dial tone. The switch enables/disables the end-user line functions which would be able to break the telemetry connection. The MICC dials a locally limited range of telephone numbers which are terminated via a telemetry user line (UTT) to the exchange COSU. This exchange and the MICC carry out a security exchange and the MICC instructs the exchange COSU via a telemetry protocol which service or sub-service provider should receive the MICC information. If desired, the service provider can have a further security dialogue with the MICC. If the security exchange is not accepted, the call is terminated by the exchange COSU, but otherwise this exchange will transmit the received MICC information to the specific service provider. A two-way data exchange can take place between the service provider and the connection circuit MICC. MICC will not perform a telemetry call if the end user's line is busy. The MICC breaks the telemetry call if an end user goes off-hook. The assistance service or the exchange COSU terminates the call upon connection.

An automatic message account (AMA) is generated, as it is the help desk or the subcontractor of the service that is charged for the call (return charge) from the end user.

Access code calls are permitted via turnover when the end-user line is not assigned for debiting purposes, if e.g. the consumer line has a service class such as the "Fast New Service Installation service" offered by the company BellSouth, USA, the consumer line can generate a limited amount of call types (such as calls requiring services, made when a telephone subscriber moves into a previously empty house that has installed telephones or telephone contacts), or the access code may be of the limited number of calls that can be made via line for this particular type of service.

MICC has a requirement to be able to disconnect, dial a number of numbers and set up a two-way conversation with COSU. These requirements are: The telemetry call to the COSU is activated by the MICC when this communication circuit is disconnected. An access code comes before the area code for the COSU destination. The first dial tone indicates the numbering of the access code. A second dial tone indicates entry of the area code, this need exists if the switch's numbering plan does not allow the access code plus an area code as a legitimate entered number. A pause is required to wait for the second dial tone if needed. The MICC will not place the call if the end-user line is busy and will instead disconnect if an end-user is disconnected when the telemetry connection is established. An application dialog is required between MICC and COSU to set up the connection, enable data transfer, display the help service, and terminate the data transfer.

The telemetry usage line UTT for connection between a switch and a personal service center COSU is bidirectional (incoming and outgoing). UTT works with the same protocol as in the case of only outgoing connection phase, but in this case the switch is designed to be able to set up the protocol vis-a-vis COSU. Only one (multi-frequency) ST pulse is used.

MICC gets in touch with the helpline by sending out the area code assigned to the connection lines in the UTT group. Calls to other than UTT lines are terminated. Successful calls are routed to the UTT groups assigned to the detention center COSU.

During the setup of the connection to effect the calls, the following functions are activated or deactivated:

Upon termination of a connection, these functions are restored. The cancellation of the automatic call notification applies to subscribers who normally have such an automatic call notification, as the cancellation applies to this function for the subsequent connection. i The next function in the list applies to subscribers who can activate a call notification by dialing a specific number, and canceling this function means that it will not be activated during the telemetry connection. Automatic redial (AR) is a function where the subscriber dials a predetermined code and then a connection will be established by redialing the last dialed number as soon as the intended recipient for that number is available. Obviously, an end user does not want to have a telemetry connection set up as soon as COSU is available. Return billing is activated to charge the help desk for the call. The audible message waiting signal (typically an interrupted buzzer tone) is deactivated so that the equipment in the MICC control center receives a normal buzzer tone and then reactivated due to the end user receiving no audible or visually perceptible signal (ie an indication by a message waiting lamp). The code restrictions that apply to screen list blocking and the numbering plan area (NPA) are disabled to allow the telemetry connection to continue even if the destination is normally blocked by the subscriber from allowing ordinary calls. Other features and functions can be added to this list if such features or functions can be thought to interfere with an incoming telemetry signal.

The following four disconnection scenarios exist:

COSU, support services or service providers are the ones who activate the disconnection.

In this case, the COSU signals are connected to UTT. The action causes the switch to transmit a disconnection (800 ms break) to the MICC, which in turn presents a connection to the switch and becomes inactive. The switching signals are connected to the COSU and the COSU informs the helpline about the terminated connection.

Switch activated disconnection.

In this case, the switch activates a disconnection (800 ms break) to the MICC. The MICC signals are connected to the switch and become inactive. The switch indicates connection for COSEU, which in turn indicates connection to the switch. COSU further informs the helpline that the connection has been terminated.

End-user activated disconnection.

In this case, the end user activates a telemetry connection disconnection by disconnecting himself. The MICC registers this and informs the COSU by means of a changed signal level, and as a result the COSU indicates connection to the switch. The switching signals are connected to the COSU, and the COSU informs the helpline that the connection has been terminated. Alternatively, a data signal may be used by the MICC to inform the COSU of a disconnected end user.

MICC enabled disconnection.

In this case, it is the MICC that activates the disconnection by connecting. The switch indicates connection to the COSU, and the COSU indicates connection to the switch and informs the assistance service of the terminated connection.

At the end of a telemetry connection, an automatic message account (AMA) is generated, using an AMA structure code 00500 with call type 005. Standardized AMA definitions are used, with the exception of the generation of the NPA and the number, and the ending of the NPA and the number has been changed. This exchange allows return debiting to the helpline. The response is defined as the time when the COSU goes off-hook. Disconnection is defined as the time when the COSU or MICC is disconnected. Alternatively, a special AMA can be used for such telemetry transfers, but such special accounting may need the end user's number and often uses a special accounting indicator for identification of a telemetry account.

Call connections to the help desk can be further routed by switch-based multi-line paging groups or automatic call distributors (ACD). An MHG for dividing the incoming service calls according to several caller lists and devices. The switch-based ACD provides intelligent distribution of incoming service calls and provides handling information to the help desk to ensure efficient organization of call center resources. E.g. can ACD smooth out the incoming telemetry calls via the helpline and provide alternative routing of incoming telemetry calls, possibly also providing call and station operation data.

The physical connections between the COSU and the auxiliary service will be the same as in the outgoing service. The connection protocol allows for two-way activation, data transfer and disconnection scenarios.

Fig. 1 shows a block diagram of how the invention can be used. A terminal in the form of a desktop computer or PC 10 in a service office is connected via a line or an inter-office connection to a telephone selector mechanism or switch 21. Alternatively, the computer 10 can be connected via an ISDN packet network. When an access number and the area code have been dialed and received by a command unit 30, a connection is set up in the switch 21 to a station service center COSU 20 which is shown here in a first service location that includes the switch 21. COSU 20 is connected to several central switches such as the switches 21 and 22, by using telemetry service lines (UTT) which can be today's simple inter-office lines for analogue or digital connection. Each of the switches 21, 22, which can be physically arranged in different connection centres, such as switches 21 and 22, have a switching grid 23 respectively. 24 for the transmission of connection signals, such as speech signals, and included the control signals for instrument reading such as counter step registration and control signals for the apparatus, according to the invention. Each of the switches comprises control processors 26 which work under the command of a program 28 which is stored in the storage 27 for regulating the operation of the switches.

When the connection between the system's command unit 30 (CU) and the COSU 20 and the service location 60 is established, the unit 30 receives from the COSU or the desktop computer T via the service center a signal to transmit data to activate the MICC into telemetry mode. Telemetry and command signals are then exchanged between the CU 30 and the COSU 20 or the desktop computer 10 and the data received from the CU 30 is transmitted from the COSU 20 to it for processing by the auxiliary service. Similarly, auxiliary control signals are sent from the computer to the COSU for transmission to the CU 30 for controlling equipment in the subscriber's home. If a subscriber picks up the phone at a telephone exchange while there is a connection between the service center and instrumentation and/or equipment other than alarm devices at the subscriber's location during a telemetry connection, such service will be quickly terminated so that the normal telecommunications service is re-established for the subscriber. However, an incoming call will receive a busy signal if the telemetry connection is active. The particular embodiment shown in fig. 1 uses an analog line for the transmission of voiceband signals, ring or tone warning signals and uses direct current detection for monitoring. The term "ringing" or "ringing" is used for expedient reasons and because it is in common parlance, but the meaning is really to describe any process of subscriber alarm activation or notification, e.g. a tone alert. For lines within ISDN, monitoring and notification signals are sent as digital signals over the D channel for the subscriber line.

UTT is a conventional interstation connection line such as an analog or digital E & M line connection or a common channel signaling line. Such long-distance lines have devices where a monitoring change at one end is signaled to the other end by means of a tone (E & M) or by an out-of-band tone or equivalent data signal. Such a remote line will be able to transmit a transmission signal that is detected in a line circuit and forwarded by a switching processor to one end of the line, to the COSU to perform a disconnection of the device in question when a subscriber is disconnected in the middle of a single access call. When an end user is disconnected during an incoming telemetry transmission that is different from an alarm service, the MICC or COSU will register the disconnection and signal connection to the switch to terminate the telemetry connection so that the end user can make a call.

COSU builds on the conventional and known COSU for connection with remote lines to a number of switches such as switches 21,...,22 and can be connected to several remote lines (a line group) to each such switch. The COSU is also connected to several help desks and service providers for enhanced service such as alarm/security maintenance, one of which is shown, which can set up calls or calls to different subscribers at the same time.

Fig. 1 shows details of a command unit 30 (CU). A protection circuit 40 is used to protect the other part of the CU 30 against damage that can be caused by electrical signals with particularly high energy. In reality, this therefore becomes an overvoltage protection, and such protection circuits are well known in the art. For calls coming into the command unit 30 from the switch 21, an alert circuit 42 is used to record the initial alert tones used to signal a connection request to the MICC 46, and the alert circuit continuously monitors the line when connected to record such signals. When such a signal is detected, the MICC is activated and communicates with the drilling computer 10 to exchange read information from instrument circuits or counter step indicators, information on counters 50 and commands to command circuits 48. When a command and/or read cycle is completed, as determined by COSU 20 will be connected to this exchange, which activates switch 21 to send a minimum 800 ms open loop signal to CU to signal a disconnection.

As long as the command unit 30 loads the line with an impedance greater than about 10 k ohms, the service center will treat the line as if it were connected. If the subscriber picks up his telephone instrument while the outgoing connection between the desktop computer and the MICC is taking place, the switch 21 will register disconnection and break the connection between the computer and the MICC by sending a disconnection signal to the MICC and a connection signal to the COSU to terminate the connection. For an incoming telemetry connection, the switch receives a disconnection signal from the CU to indicate a service need.

Arrangements for connection with connectable devices (on-hook devices) such as the connection circuit are well known in the art and can be studied in more detail in e.g. Bellcore Technical Reference TR-TSY-000030, Issue 1, June 1988.

In order to handle remotely activated (ie incoming) telecommunications calls, the CU 30 and the MICC 46 perform additional functions, the latter controlling a switch 52 on the subscriber line 50. To activate a call, the MICC 46 amplifies a disconnect signal to the line 50, and then it places a call to the help desk or service point. The switch 52 on an end user's line will overlay the normal telephone subscriber connection which would otherwise bar or block alarm calls when the subscriber uses the line or wishes to use the telephone 54. The switch 52, controlled by the MICC 46, disconnects the subscriber's telephone when an alarm device issues a message such as an alarm message from an alarm device 49, so that the message from this is continued without interruption. For incoming telemetry connections that are not alarm calls, the end user will have priority over the telemetry connection, and this will be disconnected if the end user is disconnected. In this case, the connection via the switch 52 will not be opened again. A "smart device" which can be controlled remotely and which can send a report message, e.g. an error message. For such messages, the subscriber's phone will not be disconnected, and if the subscriber wishes to make a call while the message is being sent, this message will simply be sent again after the subscriber has hung up.

Fig. 1 also includes an automatic call distributor ACD 24 which is used to distribute calls and connections from several central service points and to several ports in an auxiliary station. The switches 71, . The distributor 24 allows traffic peaks to be handled via one of the switches 21,...,22; 71,..,72. Alternatively, the output from the units 20, 70 and 73 can be connected directly via a private line or by dial-up connection with a single port or to a search group via the switching network 23 to the service location or auxiliary station 60.

Fig. 2 shows the steps carried out in a station in response to a remote telemetry call. Block 702 indicates that the station receives a primary signal (origination). Block 704 shows the start of a digit collection. Decision block 706 is used to determine if the leading digits are digits associated with a special access code such as #67 for identification of this particular class of call. If this is not a special access code, the call will be processed conventionally (action block 708). If there is a special access code, the interference features assigned to the line will be withheld for this call (action block 710) and return billing will be activated (action block 712). Among the features that are canceled during the duration of the telemetry call are the automatic call alert signals, screening lists for the outgoing call blocks, outgoing call blocks for specific number plan areas and user features such as automatic callback (the end user will automatically call the last incoming number), automatic return call; (the end user will automatically call the last outgoing number), audible message waiting signal (interrupted dial tone), and blocked primary service. In general, any feature that may interfere with the setup of the telemetry call and the tone signaling required to transmit data over the telemetry call link will be canceled for the duration of the telemetry call. Automatic callback is a feature that is not activated after the connection is terminated since the last number is that of the aid station or service location, although it would be possible to program the switch to restore this feature using the autodialed callback number stored in the switch before the telemetry connection. After all the digits in the called number have been collected, the switch 21 checks whether the dialed number is the correct one (block 714). The block 714, which is a decision block is necessary to prevent subscribers from simply making all calls in the form of collection calls by dialing a special access code. If it is found in block 714 that the dialed number is the number of one of the service locations that offers a telemetry service, the call to the dialed number is completed (action block 716). If not, the call is rejected (action block 717). After the call has ended, the MICC 46 can perform an initialization operation (handshake) to show the service location, including the use of a password so that unauthorized callers cannot gain access to this service location. Accordingly, when the call is terminated and one of the ends of the line is disconnected (action block 718), a charge report is prepared for this call, and this report includes return charges, after which the retained functions for the relevant line are restored (action block 722).

Fig. 3 shows corresponding events for an ISDN line. An ISDN switch receives a setup message from the ISDN line as the initial action (block 802). The setup message includes the dialed area code. The switch checks in block 806 a Service Access Point Identifier (SAPI) field of the setup message to determine whether or not it is a telemetry call. If it is not, the call is given conventional ISDN call processing (action block 808), but if it is a telemetry call, the line functions are withheld (action block 803) and the rest of the call is handled in essentially the same way as previously described for telemetry calls from analog telephone lines .

It must be made clear that the description given here only applies to a preferred embodiment of the invention, and various other devices can be suggested by professional personnel without this deviating from the scope of the invention, the invention as such being only limited by the subsequent patent claims.

Claims (12)

1. Procedure for establishing a special) single call to a destination in a connection switching system for the operation of a line and several other lines, CHARACTERIZED BY: deactivation of a class of subscriber functions for the line, which class of functions is identified by an identification indicator included in the special service call, while the class of functions further includes functions that may interfere with the special service call, the connection switching system being responsive to receiving a special service call from the line, and automatic deactivation of the functions that may disturb the special service call when it is on its way to the destination in the connection switching system, as this has a response to the special service call during its way to the destination. 2. Method according to claim 1, further CHARACTERIZED BY reactivating some of the class's subscriber functions for the line after termination of the special service call. 3. Method according to claim 1, CHARACTERIZED IN THAT the identification indicator is an access code to distinguish special service calls from other calls. 4. Method according to claim 1, CHARACTERIZED IN THAT the identification indicator is a special indicator in the introductory part of a message within an integrated digital service network. 5. Method according to claim 1, further CHARACTERIZED BY establishing a debit entry for the special service call so that this is debited to a subscriber or customer assigned to the destination. 6. Method according to claim 1, CHARACTERIZED IN THAT one of the subscriber functions of the class is automatic call notification. 7. Method according to claim 1, CHARACTERIZED IN THAT one of the subscriber functions of the class is automatic redial of the last outgoing call. 8. Method according to claim 1, CHARACTERIZED IN THAT one of the subscriber functions of the class is screening list blocking. 9. Switching system for establishing a special service call to a destination, CHARACTERIZED BY: circuits arranged to receive a special service call in the switching system and comprising an identification indicator for deactivating a class of subscriber functions for a line for relaying the special service call, the class of subscriber functions comprising incoming and outgoing call functions that may interfere with the special service call, and circuits in response to the special service call to advance it in the system towards the destination. 10. System according to claim 9, CHARACTERIZED BY a central auxiliary station connected via a remote line to receive call establishment signals from a subscriber having a telemetry command unit. 11. System according to claim 10, CHARACTERIZED IN THAT the station further comprises circuits for connection to a public switched telephone network in order to reach the destination. 12. System according to claim 10, CHARACTERIZED IN THAT the destination has several computers in the form of servers and further comprises one or more automatic call distributors to connect the output from one or more central auxiliary stations to the individual servers belonging to the destination.