NO176637B - Communication system with a plurality of base stations, each in a separate network - Google Patents

Description

The present invention relates to a communication system including a plurality of base stations, each in a separate network, the base station in each network being in selective communication with a plurality of subscriber stations and where each base station has means for sending control information to its subscriber stations over a radio control channel of a frequency selected by said base station from a plurality of predetermined frequencies, and wherein each subscriber station has means for receiving control information on any of said plurality of frequencies.

Such a communication system is known from US patent 4723264.

The patent covers, among other things, a signaling method in which the central station detects the calling subscriber's identification number. If the subscriber is within the network, the base station assigns a channel to the subscriber for communication. However, the patent does not disclose the use of a unique base station network number to aid in the initial acquisition of the signal by the subscriber unit.

Another previously known communication system is described in US patent no. 4,675,863.

However, the present invention intends to use such a unique network number with respect to each base station. The unique network number is used by the subscriber station to more quickly obtain the network's radio control channel in order to establish communication within the correct network.

According to the invention, the initially mentioned communication system is characterized by the fact that each base station has means for including a network number that is unique to the base station in its control information, that each subscriber station has means for processing received control information to determine the unique network number included in the control information, and that said processing means enable the subscriber station to process the control information according to whether the subscriber station is in the same network as the base station.

According to one embodiment of the communication system, each subscriber station includes means for searching for the radio control channel by sequentially sending a radio control channel acquisition message on each of the predetermined frequencies, with each acquisition message including an identification number unique to the subscriber station. In addition, each base station includes means for processing the subscriber identification number in an acquisition message received over said radio control channel to determine whether the subscriber station is in the same network as the base station, and means for sending an acknowledgment to the subscriber station that said radio control channel has been acquired by the subscriber station upon said processing of the subscriber identification number indicates that the subscriber station is in the same network as the base station.

Further features and advantages of the present invention are described in connection with the description of the preferred embodiments, and with reference to the attached drawings. Figure 1 is a block diagram of a preferred embodiment of the subscriber communication system according to the present invention. Figures 2A and 2B illustrate processing routines for establishing communications between a base station and a subscriber station in the same network as the base station. Figure 3 illustrates processing routines for refining the timing of subscriber station signal transmissions to the base station. Figure 4 illustrates processing routines for sending DC signaling information over an allocated voice data communication channel.

Glossaries of acronyms

BBP Baseband Processor

CCT Channel Board task

CCU Channel control unit

CRC Cyclic redundancy check

EEPROM Electrically Erasable Programmable Read Memory

FT Fraction time management

MUX Multiplexer unit

NID Network identification number

PCM Pulse code modulation

RCC Radio Control Channel

RELP Residual-excited linear prediction

RF Radio frequency

RPU Remote connection processing unit

RUW Refining Unique Word

SCT Subscriber management task

SID Subscriber identification number

SSB Forkswitch state buffer

TDM The time division multiplex

UW Unique word

VCU Speech Codec Unit

Referring to figure 1, a preferred embodiment of the subscriber communication system according to the present invention includes a base station 104 and a plurality of subscriber stations 41.

The base station 104 includes a switch 13, a remote connection processing unit (RPU) 14, a master clock 18, a multiplexer unit (MUX) 19 and a channel module 20. The switch 13 is connected to a central processing station 25 by means of a plurality of two-wire line instances. 26. The exchange 13 is connected to the channel module by means of a Tl connection line 28 and said MUX 19. The MUX 19 multiplexes the different communication channels in different time slots on the Tl connection line 28. The channel module 20 includes a channel control unit (CCU) 23, a speech codec unit (VCU) 24, and a modem 106. CCU 23 places communication channels in different radio frequency (RF) channels. Said VCU 24 conditions voice communication signals which are carried over the communication channels. The modem 106 prepares the transmission and reception of voice and data communication signals over an assigned RF channel. The CCU 23 transmits communication signals between the assigned RF communication channel and the assigned communication channel in an assigned time slot on the Tl connecting line 28. The RPU 14 monitors the status of the time slots on the Tl connecting line 28 and the status of the RF channels and then assigns communication channels to predetermined time slots and predetermined RF channels according to a predetermined allocation routine. The CCU 23 exchanges control messages with the subscriber stations 41 over a radio control channel (RCC) in a given time slot of a predetermined RF channel.

Each subscriber station 41 includes a modem 107, a baseband processor 112 and an internal timing generator 113. The baseband processor 112 is connected by means of a two-wire interface line 27 to a subscriber terminal, such as a telephone 115 and/or a data processor 116. The baseband processor 112 includes two software implemented modules, a subscriber control task (SCT) module 100 and a channel control task (CCT) module 105. CCT 105 is responsible for word synchronization and assembly, collision detection and resolution, and error detection. CCU 23 and all CCT * are 105 listening on said RCC must exhaustively check with respect to a valid RCC message in each RCC slot. The CCT 105 performs this task by scanning for a unique word (UW) in a window ±4 symbols about a nominal UW location, based on main system timing. The CCU 23 listens on the RCC scans for the unique word in a window ±3 symbols about the nominal UW location. A search algorithm shifts the data until it finds the UW pattern, or until all possibilities have been exhausted. As soon as the ITW pattern is found, the RCC message is considered valid only if an RCC checksum is correct. ;SCT 100 implements an RCC frequency search algorithm. The purpose of the RCC search is to allow the subscriber station 41 to find the base station 104 in the same network as the subscriber station 41 as quickly as possible and to prevent the subscriber station 41 from trying and communicating with known faulty networks. Each base station 104 has a unique network identification number (NID). Each subscriber station 41 has a unique 24-bit subscriber identification number (SID). Said SID is stored in an EEPROM in the subscriber station 41. All SID* in a particular network are stored in the network database on the base station 104.

The RCC search is either active or passive. The active RCC search is only performed when a call origin is waiting. A subscriber station 41 is accepted into a network and determines its NID only through the active search. When a call origin is not waiting, the device performs a passive search using its known home NID to reacquire the correct RCC channel.

If all of the possible RCC frequencies have been tried without success in one or the other search mode, the SCT 100 attempts a hard reset. This could potentially clear a system error that prevents the subscriber station 41 from obtaining synchronization. The hard reset also reconstructs the modem. Modem construction adopts the modem filters to the existing environmental conditions. If the handset is off hook when all frequencies have been tried without success, the SCT 100 causes a fast busy possible RCC tone to be output to the handset 115.

Every time said SCT 100 performs a reset, it reads the SID and NID from said EEPROM. If no NID exists in said EEPROM, this is set to zero by default. When said SCT 100 achieves synchronization on an RCC frequency in a passive search, it compares the received NID with the internally stored NID and rejects all RCC frequencies with non-matching NIDs.

The active RCC frequency search is only initiated when a call origin is waiting. When the call originator's hold state exits, the user hangs up the handset or the device enters an abort state. The active search then becomes a passive search. If the SCT 100 has tried all RCC frequencies without success, the SCT 100 enters an abort state and sends a reorder tone to the handset 115. This clears the call originator's hold status and forces the seeker mode to transition from active to passive. When SCT 100 decides its online work! connection, the search ends.

The SCT 100 determines the subscriber station's network affiliation and an idea through the normal call setup procedure. The SCT 100 performs a search over frequencies. Every time the SCT 100 achieves synchronization on an RCC frequency, it sends a Call Request RCC message. If the base station 104 recognizes said SID, it responds with either a call connection message if it wants to complete the call, or a delete indication message with reorder delete code if it is too busy to complete the call. In any case, the search is terminated and the NID in the data field of the RCC message is preserved in an EEPROM by the subscriber station 41 for memory retention during power supply interruptions.

If the base station 104 does not recognize said SID, it sends a deletion indication message with the unknown subscriber deletion code to the subscriber station 41. The SCT 100 then generates the next frequency on which to search for said RCC. The absence of an acknowledgment from the base station also forces said SCT 100 to generate the next frequency on which to search. A new frequency may also be required by said CCT 105 due to loss of synchronization.

After finding the correct network, the SCT 100 performs a passive search whenever it loses RCC synchronization, or switches to said RCC from a voice channel. It also performs the passive search if the network number is not confirmed but the call origin waiting status is clear. If the subscriber station 41 detects a condition with the handset off (service request), it begins an active search. In the following events, said SCT 100 causes to generate the next RCC frequency in a passive search mode: (a) a new frequency request from CCT 105 due to an AM hole detection error or a loss of RCC synchronization, (b) a return to control the channel from a voice channel, or (c) RCC synchronization achieved on the wrong network.

To speed up the passive search, the SCT 100 stores up to six frequencies corresponding to its home base station 104. When a search, active or passive, is desired, the frequency generation algorithm alternates between frequencies from a stored table of RCC frequencies and an incrementing frequency counter. This gives priority to the most likely frequencies and speeds up the acquisition of the base station after a short interruption.

Whenever said SCT 100 achieves synchronization on an RCC, it looks for a match between its stored NID and the received NID. If there is no match, the SCT 100 has achieved synchronization on the wrong network, and the SCT 100 generates a new frequency on which synchronization is attempted. If said NIDs do not match, said SCT 100 has located the correct network and the search ends.

The general routines performed in the active search mode are summarized with reference to Figure 2A. The SCT 100 in the subscriber station 41 performs a routine 120, where a retrieval message including said SID for the subscriber station 41 is sent sequentially on each of the given RCC frequencies used by the base station 104 on the subscriber station's assigned network. The RPU 14 in the base station 104 performs a routine 121 for determining whether the SID that is in the acquisition message received on a given RCC frequency matches a SID in a list of SIDs stored in the base station. If the SID in the acquisition message sent by the subscriber station matches one of the aforementioned SIDs stored in the base station 104, the base station 104 then executes a routine 122 for sending an acknowledgment message to the subscriber station over the given RCC frequency. The acknowledgment message includes the aforementioned NID for the base station. The subscriber station 41 responds to the acknowledgment message by executing a routine 123 which enables the subscriber station 41 to process messages. The subscriber station 41 also responds to the acknowledgment message by executing a routine 124 for storing the NID in the subscriber station's memory.

If said SID in the acquisition message sent by the subscriber station does not match any of the SIDs stored in the base station 104, the base station 104 sends a negative acknowledgment message to the subscriber station over the given RCC frequency. On receipt of a negative acknowledgment message, the subscriber station 104 performs a routine 125 for changing the given RCC frequency and then repeats the routine 120 when sending a retrieval message on the changed given RCC frequency.

The general routines performed in the passive search mode are summarized with reference to Figure 2B. The subscriber station 41 performs a routine 127 of sequentially receiving control messages that are transmitted over each of the RCC frequencies used in the network to which the subscriber station is assigned. On a given RCC frequency, the base station 104 executes a routine 128 with the transmission of a control message that includes said NID. For a steering message received on a given RCC frequency, the subscriber station 411 performs a routine 129 by determining whether the NID in a received steering message matches said NID that is stored in the subscriber station. If said NIDs match, the subscriber station 41 executes a routine 130 which enables the subscriber station 41 to process the control messages from the base station 104. If said NIDs do not match, the subscriber station 41 executes a routine 131 by changing the given RCC frequency on which the subscriber station receives control messages, and the routine 129 for comparing said NIDs is repeated.

The timing refinement is performed at the beginning of each voice connection established over the assigned communication channel. The purpose is to fine-tune the subscriber station's transmit symbol timing to bring it within ±3$ of the base station's main symbol clock.

To achieve a ±3% tolerance, fractional time-shifted values "A fer" are accumulated over a number of frames at the subscriber station. Each transmit burst from the base station provides a different data point in the list of fractional time-shifted value samples. Periodically, the sample mean "mean A t " is calculated to generate an estimate of the actual fractional time shift. This estimate is used to adjust the subscriber station's internal timing generator to bring it closer to the desired value. This process continues until the base station detects that the subscriber station's timing is within ±3$ of the correct symbol timing value.

The base station CCU 23 automatically enters refining operation when it is assigned a voice channel. The CCU 23 instructs the modem 106 to initiate the refining operation and proceeds to send refining bursts. Each burst contains power, symbol time management and fractional time management information for the subscriber station 41.

The base station CCU 23 successfully receives a subscriber refinement burst if a refinement unique word (RUW) is present and said CRC is verified as correct. If, at any time, base station CCU 23 fails to receive a subscriber burst, the next base station transmit burst contains a symbol timing zero. Also, if the base station determines that the connection quality for a subscriber burst has fallen below a predetermined level, the base station indicates this in a command bit group to the subscriber station by setting an "ignore FT" bit. The subscriber station then discards the fractional time information contained in the burst.

The refinement operation is successfully completed when the base station reads three successive fractional time values within ±356 of the main time signal from the master clock 18. Successful completion of refinement is signaled to the subscriber station via the command bit group by setting a "StopRef" bit. The subscriber station acknowledges the termination by clearing a "ContRef" bit on the next reverse channel burst. The subscriber station then enters voice operation. Upon detection of the recognition, the base station will enter voice operation.

Refinement is aborted by the base station after 67 frames (3.0 seconds) if the ±3% target has not been reached. This is signaled to the subscriber station via the command bit group by setting an "AbortRef" bit. Abort refinement is recognized by the subscriber station in the same way as stop refinement. The subscriber station then disconnects the voice channel. Upon detection of the recognition, the base station disconnects the voice channel.

The base station sends the termination command a second time if it fails to receive the subscriber station's acknowledgment after the first transmission (ie RUW not found or bad CRC). If the base station is still unable to receive the subscriber station's acknowledgment after the second transmission, it automatically enters voice operation if it has sent a "StopRef" bit, or disconnects the voice channel if it has sent an "AbortRef" bit.

Subscriber CCT 105 will automatically introduce refining operation upon receipt of a voice channel allocation. When the base station refinement bursts are received, the subscriber station uses the contents of a "Pwr" bit group to correct its transmit power and a fractional timing bit group to correct its symbol timing.

The fractional time offset values (a fer) received from the base station are stored as they arrive. Once five valid values are collected, the subscriber calculates a sample variance to determine their spread. Should the variance be too large, additional samples are collected. As soon as the variance is small enough, or when the valid sample count reaches 16, the sample mean value (mean A t ) is calculated and used to adjust the fractional timing signal sent to the base station. After the adjustment, the buffer operation is repeated once more.

The subscriber station CCT 105 successfully receives a base station refinement burst if the RUW is found and the CRC is verified correctly. The subscriber station ignores base station bursts that are not successfully received. The subscriber station also ignores fractional timing values when commanded to do so by the base station. There is only one case when the subscriber station ignores the power value within the burst. This is the power value within the first successful received burst (ie this power adjustment could cause a "spike" effect on the next reverse channel burst).

The refining operation is successfully completed under command from the base station. Voice operation begins immediately after the subscriber station acknowledges the base station's termination command.

Refining is aborted after 67 frames (3 seconds) under command from the base station. In this case, the voice channel is disconnected immediately after acknowledgment of the command from the base station. The subscriber station aborts refining on its own after receiving 77 frames (3.5 seconds) of bad refining burst. This time bias allows the subscriber station to receive the "AbortRef" command before timing out and disconnecting the voice channel.

Prior to a fractional time adjustment at the subscriber station 41, the sample variance must fall below a threshold. The determination of this threshold is somewhat arbitrary, but the following analysis gives us a plausible threshold value.

It is a fact that 75$ of all samples in a random process lie within two standard deviations of the mean. Thus, if twice the calculated standard deviation is found to be within the interval (-5$,+5$), one knows that 75Sé of the samples are within 5$ of the sample mean value. This provides reasonable assurance that the sample mean value is accurate and can be used for feedback adjustment.

Since the adjustment step size is T/200, where T is a symbol time, the interval (-5#,+556) will correspond to (-10,+10) in the increment steps. Therefore, the standard deviation must lie in the interval (-5,+5), or equivalently, the sample variance must be less than 25. The sample variance is easier to calculate than the standard deviation and is therefore used in the current realization. The formulas are:

"V" is the sample variance

"A tj" is the i'th calculated fractional time shift value sample

"n" is the sample size

"mean A t" is the calculated mean value A t for n samples.

The solution to refining described here allows the acceleration of the operation under good conditions, while providing robust operation under unfavorable conditions. If fractional time estimates are good, refinement is completed within 4 frames (180 ms). Under ideal conditions, a full 16 frame average needs to be calculated, which takes approx. 19 frames (855 ms). The worst case conditions could drive the algorithm to its upper limit of 67 frames (3 seconds), but it seems unlikely that speech operation would even be possible under such extreme circumstances (ie this is why refinement is aborted if the maximum count is reached).

The general routines performed by the base station 104 and the subscriber station 41 to achieve timing refinement are summarized with reference to Figure 3. The subscriber station 41 performs a routine 134 to send successive frames of refinement signal bursts which are timed by the internal timing generator 113.

The base station RPU 14 performs a routine 135 of processing each received refining signal burst in relation to the system timing signal from the master clock 18 to determine an offset value A t for each burst between the time of the system timing signal and the timing of the refining signal.

The base station CCU 23 executes a routine 136 by determining whether a predetermined number "n" of successively determined offset values a t is below a predetermined value "U". When the base station CCU 23 determines that a predetermined number "n" of successively determined offset values A t is below the predetermined value "U", it performs a routine 137 of sending a stop refinement signal to the subscriber station 41. The BBP 112 in the subscriber station 41 responds to the stop refinement -signal by executing a routine 138 which terminates the transmission of the refining signal which sends an acknowledgment signal back to the base station, and then by executing a routine 138a. The BBP 112 then executes a routine 139 which enables normal connections over the given communication channel with the base station 104.

The base station CCU 23 responds to the acknowledgment signal in routine 138 by executing a routine 138b which enables normal communications over the given communication channel with the subscriber station 41.

The base station CCU 23 also executes a routine 141 with time management of the duration "D" of the routine 136, where it is determined whether all of n successive shifted values a fer are less than the predetermined value "U". If such a determination has not been made within a certain duration "S" (ie D>S), the base station CCU 23 executes a routine 142 which sends an abort signal to the subscriber station 41. The BBP 112 in the subscriber station 41 responds to the abort signal by executing a routine 143 which sends an acknowledgment signal back to the base station, and by then executing a routine 144 which tears down the given communication channel on the base station. The base station CCU 23 responds to the acknowledgment signal from the subscriber station 41 by executing a routine 145 which tears down the given communication channel on the base station.

Prior to the expiration of the predetermined duration S defined by the routine 141 for timing the duration D of the routine 136 for determining whether a predetermined number "n" of successively determined offset values A t are below the predetermined value "U" (i.e. D<S), and prior to determining that a predetermined number "n" of successively determined offset values a t is below the predetermined value "U", the base station CCU 23 executes a routine 147 which sends the determined offset value A t to the subscriber station 41 .

The BBP 112 in the subscriber station 41 performs a routine 148 by calculating the average shifted value (average At) from the last "m" shifted values A fer received from the base station (provided that the shifted value is not unverified by being accompanied by a " Ignore FT" bit as described above). BBP 112 also performs a routine 149 for determining whether a predetermined number "p" of received verified offset values A fs are within a predetermined tolerance "R" of the average offset value (average At) calculated according to routine 148.

If BBP 112 determines according to routine 149 that a predetermined number "P" of received verified offset values A fer are within the predetermined tolerance R of the average offset value (average A t ), BBP 112 executes a routine 150 which adjusts the timing of the internal timing generator at the calculated mean offset value (mean A t ).

If BBP 112 determines, according to routine 149, that a predetermined number "P" of received verified offset values A fer are not within a predetermined tolerance of the average offset value (average A t ), BBP 112 performs a routine 151 of counting of the number of such negative determinations, and when a predetermined count "Q" corresponding to a predetermined duration is reached, BBP 112 performs the routine 150 of adjusting the timing of the internal timing generator with the calculated mean offset value (mean At).

The subscriber communication system transports DC signaling information between the two-wire line interface 27 of the subscriber station 41 and the two-wire line instance 26 of the central processing station 25. Information transmitted in the "opposite channel" direction from the subscriber station 41 to the base station 104 includes changes in the supervisory state, dialing pulse digits, and fork switch signals (flashes). Forward channel DC signaling supports features such as synchronous ringing, distinctive ringing and coin box operation.

It is desirable to provide as much transparency as possible, within the limits of the TDM nature of the system. Signaling transparency can be measured by quantifying the following performance attributes: signaling path reliability, signaling delay, and signaling resolution.

To optimize these parameters, the system uses a waveform encoding scheme to digitally transmit DC signaling information from the subscriber station line interface 27 to the central processing station line instance 26.

Changes in the fork state are monitored by the baseband processor 112 within the subscriber station 41. A timer interrupt within the baseband processor allows the fork state to be sampled every 1.5 ms, or 30 times per second. TDM frame. Each sample is stored as a single bit (handset on or off) in fork switch state buffer (SSB) 114. SSB 114 contains 60 sample bits, although typically only approx. 45 of the bit positions are actively used. The remaining bits allow for a resilient buffer overflow capability. The nominal 45 bits provide a 67.5ms window of fork switch state information. SCT 100 uses SSB to determine changes in the monitoring state such as service requests, responses and disconnections. While a call is active, SSB is also monitored for DC signaling events.

A DC signaling event can only occur during active voice operation. SSB 114 is checked with regard to incidents once a year. TDM frame (every 45 ms). An event is detected using a cluster count. Starting at the 16th bit and running up to the 45th bit in said SSB 114, the cluster count is incremented for each "on the fork" bit and de-cremented for each "off the fork" bit. If the count reaches a threshold, defined by a final cluster count (Tcc), a DC signaling event is declared. The cluster count is not allowed to become negative or exceed Tcc. The cluster count is also maintained across frame boundaries, so that the stream of fork-switch samples is considered as a coherent whole.

The cluster counting technique has the effect of detecting clusters of "on the fork" states in SSB 114, even in the presence of unexplained phenomena. Hits are rejected, based on the choice of Tcc •

As soon as a DC signaling event is detected, a subsequent transmit burst is used as a control burst. Speech information in the burst is replaced with DC signaling information using the existing speech modulation level. The oldest 30 bits of SSB data, representing 45 ms of fork switch status, are coded in the burst.

If subsequent DC signaling events are detected in SSB 114, control bursts continue to be sent in successive frames. When that happens, an additional control burst will be required after a sequence of one or more control bursts, even if no DC signaling event is declared in that frame. The only condition under which a further control burst is required occurs when the previous control burst ended with an "on the fork" bit, leaving the base station 104 in an "on the fork" state. If a further control burst is required, the baseband processor 112 in the base station 104 must ensure that the last switch fork or fork to the stand is set to "off fork" so that the VCU 24 returns to the "off fork" state.

The first six words in each control block are assigned an arbitrary flag pattern. This flag pattern allows the control block to be detected during normal voice operation.

After the f flag pattern, there are 14 words of DC signaling data. The words are organized into seven sets, where each set includes two information words. The least significant bit in each word contains no information, and is arbitrarily set to zero. However, these bits can and should be used for error detection. The remaining 15 bits in each of the words in a set collectively contain 30 bits of fork switch state information. The information is stored chronologically from the first word to the second word within the set and from the most significant to the least significant data bit within the words. To prevent false decisions due to repeated but incorrect patterns, each set is subjected to an Exclusive - or operation with a unique bit pattern.

The receiving VCU 24 in the base station 104 determines the presence of a control block, as opposed to a speech block, by simple majority voting on the flag patterns at the head of the block. If the majority voting threshold is exceeded, the block is declared to be a governing block. RELP synthesis is continued during control block processing and normal RELP data is replaced with RELP silence.

As soon as a control block is detected, the DC signaling state information it contains will also be decoded using simple majority voting. The exclusive or reshaping must be removed prior to the majority voting operation. If the majority vote fails to exceed the voting threshold, the block is rejected and no change is made to the fork switch state.

As soon as the 30-bit content of SSB 114 is decoded by VCU 24, it is converted into Tl A/B signaling bits. In the case of two-wire toggle switch status, the 30 SSB bits correspond exactly to the desired 30 bits of A-bit signaling data.

The Tl A bits are placed in a first-in, first-out queue for transmission over a PCM main channel to the base station 104. The corresponding MUX 19 supplies the VCU 24 processor with an interrupt just prior to the A-bit Tl signaling frame, allowing the processor to inject the appropriate signaling bit into the correct PCM bit group.

When no control blocks arrive to refill the A-bit queue, the oldest state is repeated ad infinitum. In the case of a DC signaling operation, said SCT 100 ensures that the last state in SSB 114 is "off fork".

After a call setup, the CCU 23 in the base station 104 initiates the VCU 24 to the "off hook" state. In the case of call origination, the CCU 23 places the VCU 24 "off fork" just prior to completion of refinement. In the case of call termination, the CCU 23 places said VCU 24 "off hook" after an answer is detected. Control bursts were not used for these monitoring state transitions.

As soon as voice operation is established, control bursts are used to send DC signaling events to the base station 104. If a disconnection is detected at the subscriber station 41, the base station VCU 24 signaling state is left "on fork" while the call is deleted via an RCC delete request burst.

By choosing the DC signaling parameters appropriately, it is possible to tune the system performance. To aid in the detection and correction of errors, the flag pattern and SSB majority votes are taken on eight bit segments (aligned to bit group boundaries). The majority vote on the flag pattern is taken over the full 12 bit groups. For SSB 114, there are four independent majority votes, one for each bit group that it contains. If any one of the majority votes fails, then the entire majority vote is deemed to have failed. The selected parameter values are as follows: Final cluster count - 15

Flag pattern majority voting - 6 of 12 (bit groups) SSB majority voting - 4 of 7 (bit groups)

The choice of the final cluster count represents a trade-off between hit rejection and the faithful reproduction of DC signaling pulses. The minimum significant "on fork" pulse duration is 29 ms "on fork", produced by a 20 pulses per second dialer that operates with a 58Sé break. With a final cluster count equal to 15, hits less than 22.5±1.5 ms will be rejected. This rejection threshold is well below the desired 29 ms, which corresponds to 18.5 test times. The threshold also means that a control block is only sent if at least 5OSé of the TDM frame is recorded with the microphone on the fork. The 45 SSB bits contain 67.5 ms of signaling information, providing 22.5 ms of forward data for the buffer to make a "go/no go" decision. Without the look-ahead data, it will not always be possible to send leading fork switch transition bits in a timely manner.

The flag pattern threshold is central to avoid false control block detections and lost control blocks. Although undesirable, false control block detection during normal voice operation is not fatal to the system. A false detection results only in a 45ms silence burst and the remote possibility of some hits on the central processing station's line instance. Far less acceptable would be the loss of a control block, or even worse a control burst, as this interrupts the subscriber's ability to perform signalling. With this in mind, the flag pattern threshold is set to six (fixed position) eight-bit (bit group boundary) fits out of a possible 12. The probability of this occurring in random noise (RELP data appears as white noise) is (2~6x8x(12 select 6) or 3.2 x IO"<12>. With a block transfer period equal to 22.5 ms, such an adaptation has an expected occurrence rate of once per 200 years during continuous voice operation. Analysis with respect to control block loss is somewhat more difficult, especially if the errors are assumed to occur in bursts, but it is suggested that this detection plan provides a good reality.

The SSB majority voting threshold allows error correction within the signaling data. As the DC signaling bits are stored in sets, corresponding SSB words are separated by many bit positions. This natural interleaving allows a breakout error to wipe out three complete sets and still not destroy the majority vote.

The speech channels that allow acceptable speech quality will also provide very reliable DC signaling using this technique. The signaling resolution for the system is 1.5 ms. This corresponds to Tl A/B signaling resolution and therefore represents an acceptable level. The signaling delay through the system is approx. 80 ms. This delay is made up of the 67.5 ms SSB window, a six millisecond transmission time and base station processing time. These measures make the system's DC signaling transparency comparable to existing digital loop carrier systems.

Similarly, DC signaling information can be transmitted from a line instance 26 on the base station 104 to the line interface 27 on the subscriber station 41.

The general routines performed by the base station 104 and the subscriber station 41 to detect and transmit DC signaling information over a communication channel assigned as a voice channel are summarized with reference to Figure 4. The originating station 155 shown in Figure 4 is either the base station 104 or the subscriber station 41 according to the origin of the DC signaling information, and the receiving station 156 is the second of two such stations.

Originating station 155 performs a routine 158 of monitoring signals on the line instance/interface, performs a routine 159 of buffering signals monitored according to routine 158, performs a routine 160 of detecting DC signaling information from the signals processed according to routine 159, performs a routine 161 of conditioning the detected DC signaling information for communication over the allocated channel instead of voice data signals by formatting the detected DC signaling information as a control block having a flag pattern in addition to the DC signaling data, and performing a routine 162 of transmitting the control block as a control signal burst in the allocated communication channel instead of speech information.

The receiving station 156 performs a routine 166 of determining the presence of a control block in a signal burst received over the assigned communication channel by recognizing the flag pattern in the signal burst. Receiving station 156 then performs a routine 167 of reformatting the DC signaling information in the control block to a standard DC signaling format for transmission to the line instance/interface. Finally, the receiving station 156 performs a routine 168 of transferring the reformatted DC signaling information to the line instance/interface of the receiving station 156.

Claims (2)

1. Communication system including a plurality of base stations (104), each in a separate network, the base station (104) in each network being in selective communication with a plurality of subscriber stations (41) and wherein each base station (104) has means (106) for sending control information to its subscriber stations (41) over a radio control channel (RCC) on a frequency selected by that base station (104) from a plurality of predetermined frequencies, and where each subscriber station (41) has means (107) for receiving control information on any one of said plurality of frequencies, characterized in that each base station (104) has means (23) for including a network number unique to the base station (104) in its control information, that each subscriber station (41) has means (100 ) to process received control information to determine the unique network number included in the control information, and that said processing means (100) enables the subscriber station (41) to process the control information according to whether the subscriber station (41) is in the same network as the base station (104). 2. Communication system as set forth in claim 1, characterized in that each subscriber station (41) includes means (100) for searching for the radio control channel (RCC) by sequentially sending a radio control channel acquisition message on each of the predetermined frequencies, with each acquisition message including an identification number which is unique to the subscriber station (41), and that each base station (104) includes means (14) for processing the subscriber identification number in a retrieval message received over said radio control channel (RCC) to determine whether the subscriber station (41) is in the same network as the base station (104), and means (106) for sending an acknowledge- tell the subscriber station (41) that said radio control channel has been acquired by the subscriber station (41) when said processing of the subscriber identification number indicates that the subscriber station (41) is in the same network as the base station (104).