KR100873591B1 - Method and apparatus for concurrently processing multiple calls in a spread spectrum communications system - Google Patents

Abstract

It is a technique that enables the processing of multiple calls in a spread spectrum communication system (100). Call processing state machines defined by the CDMA standard (e.g., IS-95 and IS-2000) are modified to include "traffic channel" substates representing mobile station 106 processing of one or more active calls. In addition, various types of call control (CC) state machines are provided to control call processing. In order to process more than one call simultaneously, the CC state machine is instantiated when it receives an indication of a particular call processing. The instantiated CC state machine is identified by a particular call and used to control the processing of that call. In receiving an indication to process an additional call, another CC state machine may be instantiated for the additional call. Thus, upon receiving an indication of call release, the call and its instantiated CC state machine are released.

Multi call processing, spread spectrum communication system

Description

METHOD AND APPARATUS FOR CONCURRENTLY PROCESSING MULTIPLE CALLS IN A SPREAD SPECTRUM COMMUNICATIONS SYSTEM}

1 is a diagram illustrating a spread spectrum communication system supporting multiple users.

2 is a block diagram illustrating one embodiment of a basic subsystem of a system.

3 shows a state machine for one embodiment of mobile station call processing.

4 is a diagram illustrating a state machine for one embodiment of mobile station control in a traffic channel state.

5 is a diagram illustrating a state machine for one embodiment of mobile station call processing capable of supporting multiple calls simultaneously.

6 is a diagram illustrating mapping between some sublayers of Layer-3 according to an aspect of the present invention.

7 to 16 are diagrams illustrating communication between a mobile station and a base station for establishing, processing, and releasing a call under various conditions.

Explanation of symbols on the main parts of the drawings

100: system 104: base station

106: mobile station 110: mobile station exchange center

214: selector unit 216: call control controller

220: data source 222: data sink

224: packet network interface 230: PSTN

240: data queue 242: channel component

244: RF UNIT 246: Antenna

248: channel scheduler 260: antenna

262: front cover 264: demodulator

266: decoder 268: data sink

270: data source 272: encoder

274 modulator 276 controller

The present invention relates to wireless communication. More specifically, the present invention relates to a method and apparatus for simultaneously processing multiple calls in a spread spectrum communication system.

Code Division Multiple Access (CDMA) modulation technology is one of several techniques to facilitate the communication that exists for numerous system users. Although other multiple access communication system technologies such as time division multiple access (e.g., TDMA and GSM), frequency division multiple access (FDMA), and AM modulation schemes such as amplitude-compounded single sideband (ACSSB), Although known in the art, the spread spectrum modulation technique of CDMA in a multiple access communication system has significant advantages over these modulation techniques. The use of CDMA technology in a multiple access communication system is assigned to the assignee of the present invention and referred to herein as "SPREAD SPECTRUM MULTIPLE ACCESS COMMUNICATION SYSTEM USING SATELLITE OR TERRESTRIAL REPEATER." US Patent No. 4,901,307, issued February 13, 1990, and entitled "System and Method for Generating Signal Waveforms in a CDMA Cellular Telephone System." ) And US Patent No. 5,103,459, issued April 7, 1992.

Typically, CDMA systems are designed to conform to one or more specific CDMA standards. Examples of such CDMA standards are "TIA / EIA / IS-95A Mobile Station-Base Station Compatibility Standard for Dual-Mode Wideband Spread Spectrum Cellular Systems", "TIA / EIA / IS-95B for Dual-Mode Wideband Spread Spectrum Cellular Systems" ( Collectively, the IS-95 standard), the TIA / EIA / IS-98A, -B, -C standards, referred to as "Recommended Minimum Performance Standards for Dual-Mode Spread-Spectrum Cellular and PCS Mobile Stations," and "cdma2000 for Diffusion Spectrum Systems" Standard "(hereinafter referred to as IS-2000 standard). New standards continue to be proposed and commercially available.

Each of the above standards defines a mechanism for handling a single call between a mobile station and a base station. This mechanism features a call processing state machine on a signaling layer (ie, layer-3) that includes multiple states and a set of allowed transitions between them. Each state of this state machine corresponds to the specific state of the mobile station (or base station) for the call to be processed. The transition to the new state occurs when any particular event occurs.

CDMA systems were originally designed to provide (mainly) voice communications. Thus, call processing state machines defined by the CDMA standard are typically designed to support a single call, which is a voice call. Typically, in a system designed to conform to a particular CDMA standard and to implement a call processing state machine defined by that standard, only one call can be processed at any given point in time, so when the active call terminates. No new calls can be processed until now. This one-call restriction limits the types of services that can be provided to the user.

As modern communication gradually develops, it is highly desirable to provide enhanced communication services that go beyond just voice or data only communication. Often, these enhanced services rely on system performance to support multiple calls simultaneously. For example, the ability to transmit voice and video (e.g., two simultaneous calls) simultaneously can be used to provide video conferencing. In some applications, it is desirable to be able to transmit voice and data simultaneously (e.g., send a file while on a call).

Therefore, in a spread spectrum environment, a technique capable of simultaneous processing of multiple calls is highly desirable.

The present invention provides a technique capable of processing multiple calls in a spread spectrum communication system. The present invention changes (or redefines) the call processing state machine defined by the CDMA standards (e.g., IS-95 and IS-2000) to represent one or more active calls to be handled by the mobile station ("traffic channel"). Include substates. The present invention also provides several types of call control (CC) state machines and uses them to control the associated call processing. In one embodiment, one CC state machine is instantiated for each call to be processed, and upon release of the related call, the instantiated CC state machine is terminated. Referring to FIG. 5, the layer 3 processing state machine is referred to as the overall state machine 500, and the call control (CC) state machine represents the voice, data, ISDN, and GSM state machines instantiated for each call.

It is also an object of the present invention to provide a method for simultaneously processing one or more calls in a spread spectrum communication system. According to this method, an instruction of a specific call to be processed is received and an CC state machine for the call is instantiated. The instantiated CC state machine is used to identify a particular call and control the processing of that call. Thereafter, one or more data transmissions associated with this particular call are exchanged. When receiving an indication of a call to be processed another, another CC state machine can be instantiated for that other call. Similarly, upon receiving an instruction to release a particular call, the call is released and the instantiated CC state machine terminates. In one embodiment, each call to be processed is associated with a particular service option connection, which includes information indicative of the set of parameters (eg, physical channels) used in the data transmission.

The instantiated CC state machine may be of a specific type selected depending on the type of call to be processed. For example, different CC state machines can be used for voice, data, video, fax, ISDN, GSM, and other types of calls. In one embodiment, the CC state machine instantiated for a voice call includes: (1) a command wait substate indicating a command wait from a base station, (2) a response wait substate indicating a wait for a user response to a particular call, (3) a call substate indicating inter-transmitter allowance for the voice call, and (4) a release substate indicating end of the voice call.

Another object of the present invention is to provide a method for supporting two or more calls simultaneously in a spread spectrum communication system. According to this method, an instruction of Call _A to be processed is received. Determine a first service option connection (SO Conn ₁ ) to use for data transmission and associate a set of one or more physical channels with that service option connection. The first call is mapped to the first service option connection and the CC state machine is instantiated to control the first call. For each subsequent call to be processed, a separate CC state machine may be instantiated. Also, upon receiving an instruction to release a particular call, the call is released and the CC state machine instantiated for that call is terminated.

In the above embodiments, when processing multiple, concurrent calls, one or more additional service option connections may be determined for use in data transmission. Each active call is mapped to one of the service option connections. When a call is released, a determination is made as to whether the service option connection of the just released call is being used by one or more active calls. If the service option connection is not in use by one or more calls, the connection is released. Similarly, when a service option connection is released, it is determined whether the physical channel (s) associated with this released service option connection are being used by another service option connection. If the physical channel is not in use by more than one active service option connection, the channel is released.

It is still another object of the present invention to provide a method for processing one or more calls in a spread spectrum communication system. According to this method, a particular communication system is selected for use and the paging channel is monitored for alert messages of the incoming call. For each call to be processed, establish one or more physical channels for data transmission and instantiate a CC state machine. It then exchanges the message for that call over the established physical channel. Upon receiving an instruction to release a particular call, in response to the reception instruction, the CC state machine instantiated for the particular call is released. Still another object of the present invention is to provide a mobile unit having a controller coupled to a receiver unit and a transmitter unit. The receiver unit receives the incoming message and the transmitter unit transmits the outgoing message. The controller receives an indication of a particular call to process, instantiates a call control state machine for that particular call, and exchanges, via the receiver and transmitter unit, one or more messages related to that particular call. This instantiated call control state machine is identified as a specific call and used for the control processing of the call. In addition, the controller can further receive an indication of another call to process and instantiate additional call control state machines for that other call. The controller also releases the call control state machine for that particular call after receiving an instruction to release the particular call.

1 is a diagram of a spread spectrum communication system 100 supporting multiple users. System 100 provides communication for multiple cells 102A-102G. Throughout this system, several mobile stations 106 are interspersed. In one embodiment, each mobile station 106 communicates with one or more base stations 104 on the forward or reverse link at any given point in time. The forward link means transmission from the base station to the mobile station, and the reverse link means transmission from the mobile station to the base station. As shown in Fig. 1, base station 104A transmits data to mobile stations 106A and 106J on the forward link, base station 104B to mobile stations 106B and 106J, base station 104C to mobile station 106C, and so on. In Fig. 1, the solid arrows indicate the data transmission from the base station to the mobile station. The dashed arrow indicates that the mobile station receives a pilot signal from the base station but no data transmission. For brevity, reverse link communication is not shown in FIG.

As shown in Fig. 1, each mobile station, especially a mobile station located near cell alarms, can receive data transmissions and / or pilot signals from several base stations. If the measured pilot signal from a particular base station is above a certain signal level, the mobile station may request the base station to add to the mobile station's active set. In one embodiment, each mobile station can receive data transmissions from zero or more members of its active set.

2 shows a block diagram of one embodiment of the basic subsystems of system 100. The MSC 110 interfaces with the packet network interface 224 of the system, the PSTN 230, and the base station 104 (for simplicity, only one base station 104 is shown in FIG. 2). The mobile station switching center 110 coordinates the communication between the mobile stations 106 in the system 100 and other users connected to the packet network interface 224 and the PSTN 230. PSTN 230 interfaces with users by a standard telephone network (not shown in FIG. 2).

Although only one selector is shown in FIG. 2 for the sake of brevity, the mobile station switching center 110 includes a plurality of selector portions 214. To control communication between one or more base stations 104 and one mobile station 106, one selector unit 214 is assigned. If no selector portion is assigned to the mobile station 106, the call control processor 216 recognizes the need to page the mobile station. The call control processor 216 then instructs the base station 104 to page the mobile station 106.

Data source 220 includes data to transmit to mobile station 106. The data source 220 provides data to the packet network interface 224, which receives the data and routes it to the selector component 214. The selector component 214 then sends data to each base station 104 in communication with the mobile station 106. Each base station 104 has a data queue containing data to transmit to the mobile station 106.

In one embodiment, on the forward link, data is divided into packets, then formatted with other control and coding bits and then encoded. Depending on the particular physical layer implementation of the CDMA system, the encoded packets may be demultiplexed into parallel streams and transmitted over one or more Walsh channels.

This data is transmitted from the data queue 240 to the channel component 242 in packets. For each packet, channel component 242 inserts the necessary control fields. The formatted packet includes a data packet, control fields, check bits, and code tail bits. Channel component 242 then encodes one or more formatted packets and interleaves (or rearranges) the symbols in the encoded packets. Interleaved packets are scrambled with a scrambling sequence, covered with a Walsh cover and spread by a long PN code, a short PN code and a PNQ code. This spread data is orthogonally modulated, filtered and amplified by the transmitter in RF unit 244. The forward link signal is sent to the antenna 246 and transmitted over the air on the forward link 250. Channel scheduler 248 located within base station 104 coordinates communication between mobile station 106 and one or more base stations 104.

At the mobile station 106, the forward link signal is received by the antenna 260 and routed to the receiver unit in the front end 262. The receiver unit filters, amplifies, quadrature demodulates, and quantizes the signal. The digitized signal is provided to a demodulator 264 (DEMOD), despread with a long PN code, a short PNI code, and a PNQ code, decursed into a Walsh cover, and descrambled by the same scrambling sequence. This demodulated data is provided to a decoder 266 that reverses the signaling function (e.g., deinterleaving, decoding, and frame check function) performed at the base station 104. The decoded data is provided to the data sink 268. The hardware described above supports the transmission of data, messaging, voice, video, and other types of communications over the forward link. Here, these various types of communications are collectively referred to simply as "data."

System 100 supports data transmission on the reverse link from mobile station 106 to base station 104. Within mobile station 106, controller 276 processes the data to transmit by routing the data to encoder 272. Controller 276 may be implemented as a microcontroller, microprocessor, digital signaling (DSP) chip, or ASIC controller configured to perform the functions described below.

In one embodiment, the encoder 272 is a United States of America, assigned to and referred to herein as "METHOD AND APPARATUS FOR THE FORMATTING OF DATA FOR TRANSMISSION." Encode the data according to the Blank and Burst signaling data format disclosed in patent " 5,504,773 ". Encoder 272 then generates and appends a set of CRC bits, adds a set of code tail bits, encodes the data and the added bits, and then rearranges the symbols in the encoded data. Interleaved data is provided to a modulator 274 (MOD).

Modulator 274 can be implemented in various embodiments. In one embodiment, the interleaved data is covered with Walsh codes, spread with long PN codes, and further spread with short PNI and PNQ codes. This spreading data is provided to the transmitter unit in the front end 262. The transmitter unit modulates the data, performs filtering and amplification, and then transmits the reverse link signal over the reverse link 252 through the air by the antenna 246.

At base station 104, a reverse link signal is received by antenna 246 and provided to RF unit 244. RF unit 244 filters, amplifies, demodulates, and quantizes the received signal to provide a digitalized signal to channel portion 242. Channel component 242 despreads the digitized signal with the short PNI and PNQ codes and the long PN code, and recovers the despread data with the appropriate Walsh code. Channel component 242 then rearranges the decovered data, decodes the deinterleaved data, and performs a CRC check function. The decoded data (eg, voice, picture, data, or message) is provided to the selector component 214 and then the data is routed to the appropriate destination. Channel component 242 may also forward the quality indicator to selector component 214 representing the received data packet status.

The physical layer used to process data in an IS-95 compliant CDMA system is disclosed in more detail in US Pat. No. 5,103,459, supra. The physical layer of another CDMA system is disclosed in US Patent Application No. 08 / 963,386, filed Nov. 3, 1997, entitled METHOD AND APPARATUS FOR HIGH RATE PACKET DATA TRANSMISSION. Is disclosed.

System 100 can be designed to conform to any CDMA standard that exists or will be adopted in the future. Each standard defines a mechanism for handling calls at mobile stations.

3 shows a state machine 300 of an embodiment for mobile station call processing. This state machine is defined by the IS-95-A standard, and a similar state machine is defined by the IS-2000 standard. Upon power up, the mobile station transitions from power up state 310 to mobile station initialization state 312.

In state 312, the mobile station selects a particular system to use. If the selected system is an analog system (eg, a GSM or TDMA system), the mobile station transitions to state 314 to initiate analog mode operation. However, if the selected system is a CDMA system, the mobile station proceeds to acquire and synchronize the selected CDMA system (ie, one or more base stations in the selected system). Once the mobile station acquires the timing of the selected CDMA system, it enters mobile station idle state 316.

In state 316, the mobile station is "on" but is not operational. The mobile station monitors the paging channel on the forward link in a message from the base station. If the mobile station cannot receive the paging channel or if another base station should be added to the active set (eg, for soft handoff), the mobile station returns to state 312 to obtain that base station. In state 316, the mobile station can receive the message or incoming call, make a call, register, initiate a message transmission, or perform some other operation. Upon initiating any of these operations, the mobile station transitions to system access state 318.

In state 318, the mobile station sends a message to the base station on one or more access channels in an attempt to access the base station, and receives the message from the base station on the paging channel. The exchange of messages depends on the particular type of communication between the mobile station and the base station (e.g. voice, data) and the originator of the message (e.g. mobile or base station), as described in more detail below. As a result of the message exchange, the mobile station may return to idle state 316 if there is no “active” communication with the base station, and proceed to mobile station control state 320 for the traffic channel once the call is processed with the base station. Prior to transition to state 320, the mobile station is assigned to the forward traffic channel for that call.

In state 320, the mobile station communicates with the base station using the established forward and reverse traffic channels. At the end of the call, the mobile station returns to state 312.

In addition, the state machine shown in FIG. 3 is described in detail in the applicable CDMA standards (e.g., IS-95 and IS-2000 standards). In a specific CDMA standard, each state shown in FIG. 3 is defined by a state machine including several substates.

4 shows a state machine for one embodiment by mobile station control state 320 for a traffic channel. In system access state 318, upon receiving the assigned forward traffic channel, the mobile station enters traffic channel initial substate 410 of state 320.

In sub-state 410, the mobile station confirms that it can receive data by the forward traffic channel, initiates data transmission by the reverse traffic channel, and synchronizes the traffic channel between the mobile station and the base station. In addition, when entering and exiting substate 410, the mobile station performs a series of other functions (e.g., adjustment of power control). The mobile station then waits for an indication from the layer 2 (for IS-2000 compliant system) or base station (for IS-95 compliant system) that obtained the forward traffic channel. Thereafter, when a call received from the base station is received, the state transitions to the command standby substate 412, and when a call is made, the state transitions to the call waiting substate 416.

At substate 412, the mobile station waits for an alert related information message from the base station. This message indicates how and when the mobile station is calling. If the mobile receives a message within a certain period of time (T _SIM ) entering the substate 410, it transitions to the mobile station waiting for response substate 414.

In substate 414, the mobile station calls in accordance with the received alert-related information message to notify users of an incoming call. The mobile station then waits for a user response. Upon receipt of a user response (eg, an indication of pressing a "response" button), the mobile station transitions to call substate 416.

In sub-state 416, the mobile station communicates with the base station through the assigned traffic channel and in accordance with the negotiated service option connection, as described in more detail below. For calls or data calls originated by the mobile station user, the user need not be notified of the call, and the mobile station enters substate 416 from substate 410. The mobile station stays in substate 416 for the duration of the call. If the mobile receives a command from the user or receives a release instruction to release the call from the base station, it transitions to release substate 418.

Substate 418 indicates the end of the call with the base station and indicates the end of the mobile station control state 320 for the traffic channel. In substate 418, the mobile station confirms call disconnection. Upon confirmation, the mobile station returns to the system determination substate of the mobile station initialization state 314.

The state machines shown in Figures 3 and 4 are "TR45 Upper Layer (Layer 3) Signaling Standard for cdma2000 Spread Spectrum Systems" on PDMA-4431, 1999. It is disclosed in more detail in the IS-95 and IS-2000 standard documents, including 11 July.

The state machine shown in FIG. 4 supports a single voice between the mobile station and the base station. In particular, if the mobile station is in call substate 416 (eg, during a voice call or data call), or if another call originated by the base station is received, the mobile station returns to command-waiting substate 412 to receive the newly received call. Notify the user of the call. To return to substate 412, it is necessary to terminate the current call, and the mobile station needs to return to mobile station initialization state 312. In general, this single call restriction prevents the CDMA system from providing multiple services such as video conferencing, multiple services (eg, voice and video).

Figure 5 shows an embodiment of a state machine 500 for mobile station call processing that can support multiple calls simultaneously. The state machine 500 shown in FIG. 5 can be used in place of the state machine 300 shown in FIG. The state machine 500 includes a power up state 510 and a mobile station respectively corresponding to the power up state 310, the mobile station initialization state 314, the mobile station idle state 316, and the system access state 318 of FIG. An initialization state 512, a mobile station idle state 516, and a system access state 518. However, the mobile international language state 320 by the traffic channel replaces the traffic state 520 including the traffic channel initialization substate 522, the traffic channel substate 524, and the release substate 526.

In one embodiment, states 512, 516, 518 implement similar to states 312, 316, 318, respectively. In one embodiment, the traffic channel initialization substate 522 and the release substate 526 are implemented similarly to those described for the traffic channel initialization substate 410 and the release substate 418 of FIG. 4, respectively.

Upon power up (step 510), the mobile station selects and acquires a particular system to use and synchronizes to that selected system (state 512). The mobile station then monitors the paging channel on the forward link for messages from the base station (state 516) and receives one or more operations (e.g., receive or call a message or incoming call, register, perform a message transmission). Or the like). In performing some of these operations, the mobile station sends a message to the base station on an access channel and receives a message from the base station on a paging channel (state 518) to establish a traffic channel for communication. The mobile station then enters traffic state 520 and stays in this state while one or more calls are pending. Once all calls are released, the mobile station returns to mobile station initialization state 512.

Upon entering traffic state 520 for the first call, the mobile station synchronizes to the assigned traffic channel (substate 522). The mobile then transitions to traffic channel substate 524 and, upon receipt of the appropriate message (eg, call setup message), instantiates or invokes a call control (CC) state machine for that call. For example, a mobile station instantiates a voice CC state machine 530 for a voice call, data CC state machine 540 for a data call, and ISDN CC state machine 550 for a call with an ISDN network. For example, GSM CC state machine 560 may instantiate a call with a GSM network, or other CC state machine for another communication type. These CC state machines are used to control the processing of related calls.

While in traffic 520, if another call is originated or received, the mobile station instantiates another CC state machine for that new call. In one embodiment, one CC state machine is instantiated for each call that is processed. The CC state machine is used for direct control of an associated call and processes a call control message associated with that particular call. In this way, there can be multiple (L) CC state machines at any given point in time, where L = 0,1,2,3 and the like. The mobile station stays in traffic 520 as long as there is at least one pending call. At the end of each call, the CC state machine of that call is released and the mobile station determines if the released call is the last pending call. If the released call is the last call, then the mobile proceeds to release substate 526.

In certain CDMA systems, the (lower) layer-3 state machine is implemented using a state machine 500 (including states 510, 512, 516, 518, 520). State machine 500 defines the interaction between the mobile station and the base station and is not limited to any particular call. State machine 500 may be used to support any number of calls simultaneously. The CC state machine is call specific and can be implemented based on system conditions. In addition, CC state machines can be added, removed, or modified (independent of state machine 500) to provide different and / or additional services. The use of multiple CC state machines facilitates independent access and release of calls.

6 illustrates mapping between some layers of lower layer-3 according to an embodiment of the present invention. As shown in FIG. 6, the lower layer-3 is a call control (CC) sub on the top of the service option control (SOC) sublayer 614 on top of the radio resource control (RRC) sublayer 616. Layer 612. RRC sublayer 616 defines the physical traffic channel that can be used for data transmission. SOC sublayer 614 defines a set of parameters used for data transmission, such as multi-transmission options, power control, forward link traffic channel characteristics, and the like. Call control sublayer 612 identifies the set of pending calls to process.

As shown in FIG. 6, a call (Call _x ) is processed in the CC sublayer 612 and mapped to a particular service option connection (SO Conn _N ). In the example shown in FIG. 6, Call _A is mapped to SO Conn ₁ , Call _B is mapped to SO Conn ₂ , and Call _C is also mapped to SO Conn ₂ . Subscripts A, B, and C represent the call identifier (CALL_ID) of the pending call, and subscripts 1 and 2 represent the connection reference code (CON_REF) of the established service option connection.

Each service option connection identifies one or more physical channels to use for data transmission. In the example shown in FIG. 6, SO Conn ₁ is mapped (ie used) to a dedicated control channel (DCCH) and an auxiliary channel (SCH), and SO Conn ₂ is mapped to a base channel (FCH) and an auxiliary channel (SCH). .

As each call connects, a new CC state machine (named Call _x ) is instantiated. The instantiated CC state machine is the type selected based on the type of call being processed (eg, voice, data, ISDN, GSM, etc.). Each CC state machine type includes a number of substates that are unique to each state machine type. CDMA systems can be designed to support several different CC state machine types, and add other CC state machine types for new call types (such as pictures) as needed or desired.

As shown in Fig. 6, any number of calls can be processed simultaneously. Furthermore, one call or multiple calls can be mapped to each service option connection. One-to-one mapping between calls and service option connections can be used to implement voice communications in accordance with IS-95 standards. In some cases, you can also use a service option connection (that is, CON_REF) as a CALL_ID. In one embodiment, the call-to-service option connection mapping is maintained by both the mobile station and the base station in order to support many-to-one mapping between the call and the service option connection. In addition, when the last call mapped to a specific service option connection is released, the service option connection is also released. Similarly, when a service option connection immediately before being mapped to a specific physical channel is released, the physical channel may be released.

Service option connection (SO Conn _N) defines a set of parameters used to transmit data (called the service option SO _N), it is identified by a service option connection reference numeral (CON_REF _N). In one embodiment, this service option connection is local to the mobile station and the base station.

Service option access is negotiated via a "service negotiation" procedure. In one embodiment, if the service option connection needs to support a new call while the mobile station is in traffic state 520, use the service negotiation procedure to accomplish the service option request and assignment. Examples of these procedures are summarized in the IS-2000 standard document. In addition, other service negotiation procedures may also be implemented and are within the scope of the present invention.

In some embodiments, physical channels are established through service negotiation. In such embodiments, the service negotiation procedure may be designed to include the exchange of channel configuration information with one or more new traffic channel requests. The requested physical channel can then be connected and configured using the negotiated channel configuration information. At the end of the service option negotiation between the mobile station and the base station, the requested physical channel is established to wait for transmission.

In one embodiment, several different types of CC state machines are provided to support different types of calls. Examples of some CC state machine types include the following.

Voice: The voice CC state machine type provides for voice, circuit data, and some other services. Circuit data is transmitted over a circuit (i.e., a dedicated link) established for the connection, similar to a voice call. Signaling for circuit data is not in-band. The negative state machine can be implemented similarly to the IS-95 call state machine (shown in FIG. 4).

Packet data: The data CC state machine can provide for packet data. Implementation of this state machine may be based on the conditions of a particular CDMA system. In one embodiment, once call control is made via data transmission, the data state machine can be implemented as a null CC state machine (ie, without state machine).

ISDN: An ISDN CC state machine type can be provided for communication with an ISDN network.

GSM-MAP: The GSM-MAP CC state machine type may be provided for communicating with a GSM-MAP network.

In the specific embodiment shown in FIG. 5, the voice CC state machine 530 is divided into four substates: command standby substate 532, mobile station response wait substate 534, call substate 536, and call release sub. State 538. In general, substates 532, 534, and 536 correspond to substates 412, 414, and 416 of FIG. 4, respectively. At the end of the voice call, the voice CC state machine transitions to the call release substate. At the end of the voice call, the CC state machine for this call is released.

In one embodiment, each call may be identified by a unique call identifier (CALL_ID) to facilitate tracking of calls and processing of instantiated CC state machines in a multiple concurrent calling environment. In one embodiment, CALL_ID is " local " in the mobile station <-> MSC path and is selected by the call originator. The implementation of the local CALL_ID may allow the same CALL_ID to be used simultaneously by multiple mobile stations. The CALL_ID may be similar to the "call reference" of the ISDN and the "transaction identifier" of the GSM system.

Once the CC state machine for a particular call has been established, subsequent call-specific transmissions (e.g., flash related information messages) between the mobile station and the base station may include a CALL_ID so that they can route the transmission to the appropriate CC state machine. In one embodiment, without ambiguity, the CALL_ID may mean CC state machines that are different from the (IS-95) voice state machine. By such an implementation, signaling in accordance with the IS-95 standard can be generated to maintain backward compatibility with existing IS-95 systems. When a single voice call or circuit switched data or fax call is active, add a field (which may be optional) to identify the type of CC state machine (CC_Type) in the appropriate message, although only minimal changes may be required. . In some embodiments, since the signaling is in band, the packet data call may not require CALL_ID.

In one embodiment, a CC state machine is defined as the ability to support multiple calls per connection, similar to that of an ISDN network. Resources supporting multiple calls per connection may be provided by the mobile switching center, and this process may be transparent to the mobile station. For example, the ISDN may allow for the presence of multiple calls (CALL_ID) at the mobile station for 3-way calls. In this case, the mobile station explicitly handles the presence of different calls. However, in the ANSI-41 wireless system, after the mobile switching center handles the explicit call presence, the mobile uses a flash related information message to signal the state change of the 3-way call to the mobile switching center. The mechanism for handling such multiple calls per connection is disclosed in more detail in TIA / EIA-664, which is incorporated herein by reference.

The present invention can be implemented with minor modifications within the framework of call processing state machines generally defined by IS-95 and IS-2000 standards. Referring again to FIGS. 3 and 4, upon entering the mobile station control state 320 by the traffic channel from the mobile station access state 318 (of FIG. 3), the mobile station is generally in accordance with the current IS-95 and IS-2000 standards. As is done, the process proceeds to traffic channel initialization substate 410. In traffic channel initialization substate 410, the mobile enters a newly defined " traffic channel " substate. This new substate replaces the command wait substate 412, the mobile station response wait substate 414, and the call substate 416. One or more timers may be combined in substate 412 and substate 412 to provide the mandatory timeout indicator implemented by the current CDMA standard.

7 shows a communication diagram between a mobile station and a base station for processing a first call, which is a voice call received (ie, terminated) by a mobile station. As used herein, a mobile station termination call is a call originating from and received by a mobile station switching center. While in mobile station idle state 516, the mobile receives a generic paging message containing a new service option SO _N from the paging channel. The mobile station then enters a system access state 518 and responds with a paging response message on the access channel. The mobile station then receives an Extended Channel Assignment Message (ECAM) that includes the assigned physical channel. After receiving the ECAM, the mobile station transitions to traffic channel substate 524. While in substate 524, the mobile station receives a call establishment message that includes a CC state machine type (CALL_Type), a call identifier (CALL_ID _X ), and a service option connection (CON_REF _N ) for this call. In this particular example, CC_Type is negative. Upon receipt of the call setup message, the mobile station instantiates a CC state machine of a particular (voice) CC type.

In the command-waiting substate 532 of the instantiated voice CC state machine, the mobile station notifies the user of the incoming call (eg, by calling) and waits for a user response. In some system implementations, this call setup message may be omitted for the first call (ie, a reference value that can be used for CALL_ID and CON_REF), and CC_Type is signaled via ECAM. In this case, the CC state machine may be instantiated when entering the traffic channel substate 524.

The mobile station then performs a service negotiation procedure with the base station. In one embodiment, as part of the service negotiation procedure, the mobile station receives a service request message with a service configuration record (SCR) including the newly added service option SO _N. The set of service negotiation messages are then exchanged between the mobile station and the base station when negotiating parameters for the call, which may include a service option number. At the end of service negotiation, the mobile station receives a service connection message that includes a newly added service option SO _N and an SCR with CON_REF _N for the assigned service option connection.

In one embodiment, service negotiation and the establishment of the resulting service option connection may be made prior to receipt of the call establishment message. In this case, CON_REF _N of the call establishment message corresponds to the connection reference code of the established service option connection.

Upon receiving an alert related information message containing CALL_ID _X assigned to this call, the mobile transitions to mobile station response wait substate 534. The mobile station then calls and waits for a user response. After receiving the user response, the mobile station sends a connect command that includes CALL_ID _X. The mobile station then transitions to call substate 536, exchanging flash related information messages with the base station. Data associated with this call is transmitted on the established physical channel. As shown in FIG. 7, CALL_ID is included in each call specific message so that the message is properly routed and processed.

8 shows a communication diagram between a mobile station and a base station processing a first call, which is a data call received by a mobile station. The normal paging message, paging response message, and ECAM are exchanged and processed in a similar manner as described in FIG. Upon receipt of the ECAM, the mobile station transitions to the traffic channel substate. Upon receipt of the call setup message, the mobile station instantiates a CC state machine of a particular (data) CC_Type, which CC state machine is located in the call substate. The mobile station also performs a service negotiation procedure with the base station in a manner similar to that described above. At the end of service negotiation, the mobile station receives data transmissions from the base station on the assigned physical channel.

9 shows a communication diagram between a mobile station and a base station processing a first call, which is a voice call sent by a mobile station. While in mobile station idle state 516, the mobile station receives a call connection request from the user. In response, the mobile station sends an Origination Message, including information about the physical channel, the new service option SO _N , the CC Type Req of a particular type (CC Type Req), CALL_ID _X , and the dialed number. ) Is sent. The mobile station then receives an ECAM that includes the assigned physical channel.

Similar to Figure 8, upon receipt of an ECAM, the mobile station transitions to a traffic channel substate. Upon receipt of the call establishment message, the mobile station instantiates a CC state machine of a particular (data) CC_Type, which is located in the call substate.

Fig. 10 shows a communication diagram between a mobile station and a base station processing a first call, which is a data call sent by this mobile station. The mobile station diagram in which the data call originates is similar to the diagram of the mobile station in which the voice call of FIG. 9 originates, except that the mobile station instantiates a data CC state machine 540 after receiving a call establishment message. At the end of service negotiation, the mobile transmits data on the assigned physical channel.

11 shows a communication diagram between a mobile station and a base station for a subsequent (ie, second or greater) call, which is a voice call received by the mobile station. The mobile station switching center transmits a call connection request, and in response, the base station transmits a call setup message including, for example, CC type, CALL_ID _X , CON_REF _N. Upon receipt of the call setup message, the mobile station instantiates a CC state machine 530 that is of a particular (voice) CC type indicated by a particular CALL_ID _X. The mobile station performs mapping between CALL_ID _X and CON_REF _N.

For this new voice call, the mobile station may transition to command-waiting substate 532 to conduct a service negotiation procedure. The mobile station receives a service request message containing a new service option (SO _N ) for this call. At the end of the service negotiation, the mobile receives a service connection message with a service configuration record including the assigned SO _N , CON REF _N , and other related parameters. Subsequent communication between the mobile station and the base station proceeds in a manner similar to that for the first call shown in FIG. Messages about these voice calls and other calls are identified by the CALL_ID assigned to the call (except as far as possible except the exception of the first call). The data call may use in-band signaling.

12 shows a communication diagram between a mobile station and a base station for a subsequent (ie, second or greater) call, which is a voice call originated by the mobile station. While in traffic channel substate 524, a call connection request is received from a user. In response, the mobile station transmits a call setup request message that includes, for example, the requested CC Type Req and the CALL_ID _X assigned to the call. In one embodiment, the call originator can assign a CALL_ID to the new call (in this case, the mobile station). The mobile station then receives a call establishment message that includes the assigned CC type, CALL_ID _X , and CON_REF _N. Upon receipt of the call setup message, the mobile station instantiates a CC state machine 530 of the particular (voice) CC type indicated by the particular CALL_ID _X. The mobile station performs mapping between CALL_ID _X and CON_REF _N.

For voice calls originating from this new mobile station, the mobile station transitions to the call substate 536 and transmits a call generation message that includes, for example, the dialed number and CALL_ID _X. The mobile station then performs a service negotiation procedure. In one embodiment, service negotiation may occur prior to sending a call generation message from the call substate to the mobile station. The service negotiation message includes the new service option SO _N and related parameters. At the end of the service negotiation, the mobile station receives a service connection message with a service configuration record containing the assigned SO _N , CON_REF _N , and associated parameters. The flash related information message may be exchanged between the mobile station and the base station in a manner similar to that described above in FIG. In addition, messages of this call and other calls are identified by the assigned CALL_ID.

13 shows a communication diagram between a mobile station and a base station that releases a voice call (not the last call) by the mobile station. While in the call substate 536 for this call, upon receiving a call release request from the user, in response, the mobile enters a call release substate 538. The mobile station then sends a call release message that includes the CALL_ID _X of the call to be released. In response, the mobile station receives a call release confirmation message that includes CALL_ID _X. It also terminates the CC state machine for this call.

When the release of this call removes the service option connection (determined by reviewing the call service option connection mapping), a service negotiation procedure is performed, whereby the service option connection related message is exchanged between the mobile station and the base station. Mobile station should release CON_REF _N Send a service request message with a service configuration record comprising a. At the end of service negotiation, the mobile station will release CON_REF _N Receive a service connection message comprising a. Similarly, the channel can be released if it is not needed to support any pending call.

14 shows a communication diagram between a mobile station and a base station for releasing a voice call (not the last call) by a mobile station switching center. While in call substate 536 for this call, a call release request is received by the base station, and in response a call release message is sent to the mobile station that includes the CALL_ID _X of the call to be released. Upon receipt of the call release message, the mobile station enters a call release substate 538. The mobile station then sends a call release confirmation message containing the CALL_ID _X of the call to be released.

When the release of this call removes the service option connection, a service negotiation procedure is performed so that service option connection related messages are exchanged between the mobile station and the base station. The mobile station receives a service request message with a service configuration record containing CON_REF _N to release. At the end of service negotiation, the mobile station receives a service connection message with a service configuration record containing CON_REF _N to release. Similarly, a physical channel may be released if it is not needed to support any pending call.

15 shows a communication diagram between a mobile station and a base station that releases the last voice call by the mobile station. While in the call substate 536 for this call, a call release request is received from the user. In response, the mobile enters call release substate 538 and transmits a call release message that includes the CALL_ID _X of the call to be released. The mobile station then receives a call release confirmation message that includes CALL_ID _X. Since this is the last call, the service option connection and the physical channel for this call can be released by exchanging Radio Resource Control (RRC) related messages. In particular, the mobile station sends a release command. Thereafter, in response, the mobile station returns to the mobile station idle state 516 after receiving the release command.

16 shows a communication diagram between a mobile station and a base station for releasing the last voice call by the mobile switching center. While in the call substate 536 for this call, a call release request is received by the base station, and in response, a call release message containing the CALL_ID _X of the call to be released is sent to the mobile station. The mobile station then enters the release substate 538 and transmits a call release confirmation message that includes CALL_ID _X. Since this is the last call, the physical channel used for this call can be released in a manner similar to that described above with respect to FIG. 15 by exchange of RRC related messages. The mobile station then returns to mobile station idle state 516.

7-16 show a series of diagrams illustrating a particular implementation of call processing by a mobile station and a base station in accordance with an aspect of the present invention. Different message types and combinations may be used to implement call processing, which is within the scope of the present invention.

The components in the base station and mobile station described above can be implemented in a variety of ways. The transmitter and receiver units of the mobile station and base station may be implemented in one or more integrated circuits, individual components, or a combination thereof. The controller of the mobile station may be implemented as one or more integrated circuits, application specific integrated circuits (ASICs), digital signal processors (DSPs), controllers, microprocessors, other circuits and / or software designed to perform the functions disclosed herein. Other components of the mobile station and the base station can be implemented in a combination of hardware and software in a manner known in the art.

The present invention disclosed herein can be applied to a plurality of spread spectrum communication systems. The present invention can be applied to existing spread spectrum systems and new systems under continuous investigation. Certain CDMA systems are disclosed in the aforementioned US patent application Ser. No. 08 / 963,836. Other CDMA systems are disclosed in the aforementioned US Pat. Nos. 4,901,307 and 5,103,459.

The foregoing description of the preferred embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be apparent to those skilled in the art, and the inherent principles defined herein may be applied to other embodiments without the use of creativity. Thus, it is not intended to be limited to the embodiments shown herein but to be accorded the widest scope consistent with the principles and novel features disclosed herein.

As described above, the present invention provides an technology capable of processing multiple calls in a spread spectrum communication system, thereby providing an improved communication service beyond just voice or data only communication.

Claims (15)

In a spread spectrum communication system, an apparatus for processing a call, A controller that receives an indication of a first call and instantiates a first call control state machine of a type according to the type of the first call, wherein the first call control state machine is configured to control the processing of the first call. Used to handle calls. The method of claim 1, The controller receives an indication of a second call and instantiates a second call control state machine of a type according to the type of the second call, wherein the second call control state machine is used to control the processing of the second call. Device for processing. The method of claim 1, The controller determines a first service option connection for the first call, and the first service option connection includes information indicating a set of parameters to be used for data transmission on the first call. The method of claim 3, wherein And the parameter set comprises a parameter identifying one or more physical channels to be used for data transmission relating to the first call. The method of claim 2, The controller determines a second service option connection for the second call, wherein the second service option connection includes information indicating a set of parameters to be used for data transmission on the second call. The method of claim 5, wherein And wherein said parameter set comprises a parameter identifying one or more physical channels to be used for data transmission on said second call. A device for simultaneously processing a call in a spread spectrum communication system, A controller that receives an indication of a first call to be processed, determines a first service option connection to be mapped to the first call, and instantiates a first call control state machine of a type according to the type of the first call, The first control state machine is used to control the processing of the first call, and the controller establishes a set of one or more physical channels associated with the first service option connection to be used for data transmission, simultaneously processing the call. Device. The method of claim 7, wherein The controller instantaneously creates a separate call control state machine for each subsequent call to be processed, and wherein the instantiated call control state machine is of a type according to each subsequent call type. The method of claim 7, wherein The controller determines a service option connection to be used for data transmission for each subsequent call and maps each subsequent call to a separate service option connection, simultaneously processing the call. The method of claim 7, wherein In response to an instruction to release a particular call, the controller releases an individual call control state machine associated with the particular call and simultaneously handles the call. The method of claim 10, The controller determines whether a particular service option connection is mapped to any active call, and if the particular service option connection is not mapped to any active call, releases the particular service option connection and simultaneously handles the call. Device. An apparatus for processing a call in a spread spectrum communication system, A first state indicating a period of synchronization with a specific communication system, a second state indicating a monitoring period of a paging channel, a third state indicating a period for connecting to a base station of the specific communication system, and a fourth indicating processing of one or more active calls And a controller having a call processing state machine including a state, wherein each active call is associated with a call control state machine. The method of claim 12, And the call control state machine for each call to be processed is of a type selected based on the type of each call to be processed. The method of claim 12, And the fourth state comprises a first substate indicating data transmission of a traffic channel, a second substate indicating data transmission for a particular call, and a third substate indicating termination of the specific call. The method of claim 12, The call control state machine associated with a voice call or data call is A first substate indicating waiting for an alert with an information message to process each call; A second substate indicating waiting for a user response for each call; A third substate indicating an allowable period of transmission for each call; and And a fourth substate indicating the end of each call.

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