JP2003530018A - Method for enabling mobile stations to receive circuit switched pages - Google Patents

Abstract

(57) [Summary] The present invention relates to a mechanism for notifying a mobile station performing packet-switched data switching activity of the reception of a circuit-switched paging message in a GSM communication system. The radio link control / medium access control block is operable in a duplex transfer mode (310) and responds to packet switched data exchange activity in response to a mobile station currently performing packet switched data exchange activity (330). To the mobile station by inserting it into the corresponding packet data channel. The mobile station monitors the combined control channel to terminate the packet switched data switching activity session and set up circuit switched voice switching activity including simultaneous voice and data transmission. As a result, simultaneous voice and data transmission occurs in the dual transfer mode (350).

Description

Detailed Description of the Invention

FIELD OF THE INVENTION The present invention relates generally to signal-based communication in GSM communication systems. More particularly, it relates to a method for receiving a paging message from a circuit switched data area when a mobile station is exchanging packet switched data.

BACKGROUND OF THE INVENTION Global System for Mobile Communications (GSM) General Packet Radio Service (GP)
RS) allows service subscribers to send and receive data in end-to-end packet transfer mode without using network resources in circuit-switched mode. GP
Using RS, if the data transmission characteristics are i) packet based, ii
) If it is intermittent and aperiodic, iii) it may transfer a small amount of data frequently, for example 500 octets or less, or iv) it frequently transfers a large amount of data, for example hundreds of kilobytes or more. Radio and network resources may be used efficiently when there is a possibility to transfer. User applications can include internet browsers, emails, and the like.

The European Telecommunications Standards Institute (ETSI) GSM specification defines a so-called “mobile station class” for GPRS mobile stations. The mobile station class defines some behaviors to be followed regarding operation in packet mode, circuit switched mode, or both packet switched and circuit switched modes. For example, one such mobile station class is the Class A mobile station, which supports simultaneous connection, monitoring, activation, paging, and traffic flow for both circuit-switched voice and packet-switched data services. Class B mobile stations, on the other hand, shall only support simultaneous connection, monitoring and operation with circuit-switched voice and packet-switched data services, including call and traffic flows, which are possible on services based on exclusive interrelationships. It is defined. Class C mobile stations are defined as supporting only non-simultaneous connections with circuit switched voice or packet switched data services, ie exclusive interconnections.

Mobile station classes may also be assigned or changed by the user in some cases, with some restrictions, such as manufacturer options and device restrictions. For example, a user application may issue a command to change the mobile station class of the currently used subscriber device. Therefore, the mobile station class is treated as an "effective" class. This is because the user has some control over the identity of the mobile station class.

A mobile station with one receiver / transmitter specifies the required channelization and signaling technology capable of handling simultaneous GSM voice and packet sessions with ETS.
Efforts to develop the I GPRS specification are currently ongoing. Such efforts have developed a dual transfer mode (DTM) that allows GSM voice and GPRS or EDGE data to be exchanged on the same radio frequency (RF). When the mobile station is operating in the dual transfer mode, the operation contents of the mobile station are the active circuit switched voice connection in the dedicated mode, and the active packet switched temporary block flow (TBF) in the GPRS / EDGE packet transfer mode. including.

[0006] Current GPRS networks are circuit-switched in that they send paging messages for circuit-switched services over the same channels that GPRS networks use for packet-switched services, namely GPRS paging channels or packet-related control channels. It includes a process for coordinating the transmission of paging for both data services and packet switched data services. As a result, in order to receive the paging service, the mobile station may use the Packet Associated Control Channel (PACCH) while it is currently performing packet switched transfers, or it may be currently packet switched or circuit switched data transferred. If you have not done
The GPRS paging channel needs to be monitored.

As shown in FIG. 1, a mobile station 100, such as a wireless telephone device, includes a base station 106.
To the circuit switched network 102 and packet data network 104 by transmitting signals to and receiving signals from the base station 106. The base station 106 is connected to the base station controller 108 and
Is connected to the mobile switching center 110 through an interface 112, commonly referred to as the "A interface", which
02 functions as an interface. As a result, circuit-switched data can be transmitted between mobile station 100 and circuit-switched network 102 via a signal path that includes base station 106, base station controller 108, and mobile switching station 110.

Similarly, the base station controller 108 is connected to a serving GPRS support node (SGSN) 114, which is
It continuously tracks the location of the mobile station 100, provides security and access control, and acts as an interface to the packet data network 104. As a result, the base station 106, the base station controller 108, and the SGSN
Packet switched data may be transmitted between mobile station 100 and packet data network 104 via signal paths including 114.

Prior art GPRS networks typically include a mobile switching center 110 and an SGSN 114.
An optional interface 116, commonly referred to as the "Gs interface," connecting the and enables the mobile station operating in packet transfer mode to receive circuit-switched paging messages. Rather than sending a paging message from the mobile switching center 110 to the mobile station by the base station controller 108 via the circuit switched paging channel on the Coupling Control Channel (CCCH), the Gs interface 116 allows mobile switching via the Gs interface 116. The station 110 sends the circuit switched paging information directly to the SGSN 114. This allows the mobile station 100 to receive the circuit switched paging message while performing packet switched data transfer.

However, a problem associated with providing a Class A capable mobile station that operates in an environment that does not support the optional Gs interface 116 is that it causes packet transmission between the mobile station 100 and the packet data network 104. When performing packet-switched data transfer in which data is exchanged, the mobile station 100 does not stop receiving data from the packet data channel (PDCH) and receives the circuit-switched paging block. It is impossible to make a schedule. As a result, the throughput of packet data is reduced. This is because the retransmission must be done to recover the lost data block. Furthermore, the difference in the organization of the multi-frame structure of the packet data channel over which packet switched data is transmitted, and the page and access grant channel (PAGCH
The difference in the organization of the multiplex frame structure of the combined control channel (CCCH) over which (a) is transmitted makes it difficult to schedule the reception of circuit switched paging blocks by mobile stations during GPRS or EDGE packet transfers.

For example, as shown in FIG. 2, the packet data control channel is a multiplex frame 10 having 52 frames 102 and 12 data blocks B 0 -B 11.
It has the shape of 0. In this case, each data block B0-B11 is located on four time division multiple access (TDMA) frames. An "idle" or "search" frame 106 located after each of the three data blocks allows the mobile station to perform neighbor cell signal measurements, synchronization and synchronization status confirmation on adjacent cells, interference measurements, and so on. Each data block B0-B11 consists of four frames, each frame having a frame period f equal to 4.61538 ms and 18
． It has a block period b equal to 4616 milliseconds. On the other hand, each idle frame 106 has a frame period f, i.e., an idle frame period I equal to 4.61538 milliseconds. Packet data channel multiplex frame 10
The total period of the 0 structure is equal to 240 milliseconds.

On the other hand, the joint control channel is a multiplex frame 10 having 51 frames 110.
8 and the frame period f of each frame is equal to 4.61538 milliseconds. Multiple frames are paging and access grant channels, broadcast channels 4
It has nine groups 1-9 of four frames, including one contiguous frame block 114 and two idle frames 116 located between each group of eight frames. The total period of the multi-frame 108 structure for the paging and access admission control channel is equal to 235.385 milliseconds.

As is clear from FIG. 2, multiple frames 1 for packet data channels
The structure of 00 is different from the structure of the multiplex frame 108 for the joint control channel. As a result, the two channels are in a non-harmonic relationship so that the packet data control channel and the joint control channel are out of phase with each other as a function of time. Since the mobile station can read the circuit-switched paging block only during the time corresponding to the idle frame 106 of the packet data control channel, the mobile station performs the GPRS or EDGE packet transfer while it is performing the circuit transfer. It is difficult to schedule the receipt of exchange paging blocks. Moreover, since the total periods of the multiplex frames 100 and 108 are not equal, the paging group referenced by the idle frame at some point will change over time, and the mobile station within the idle frame will see it during packet transfer. The number of suitable paging blocks that can be seen is limited.

Therefore, there is a long felt need to develop a method for a mobile station to receive and process paging messages from the circuit switched area while operating in packet transfer mode. The features of the invention believed to be novel are set forth in the appended claims. The invention may be best understood, together with other objects and advantages of the invention, when the following description is read with reference to the accompanying drawings. In several drawings,
Similar elements have similar reference numerals.

Detailed Description of the Preferred Embodiments The present invention is a method for notifying circuit switched paging messages to mobile stations in class AGPRS duplex transfer mode operating in packet transfer mode. The mobile station notified of the circuit switched paging message terminates the temporary block flow (TBF) currently exchanging packet switched data. And to set up a circuit-switched voice connection for circuit-switched paging messages,
Return to Coupling Control Channel (CCCH) with random access. The combined control channel is a signaling channel that establishes simultaneous voice and data channels due to dual transfer mode requirements. As a result, the mobile station can continue the previously interrupted packet data transfer and obtain the circuit switched voice session.

As shown in FIG. 3, the communication network 200 has a mobile switching center 202 and a plurality of cell sites 204. Each cell site 204 has a base station 206 that connects to a base station controller 208. Protocol control unit 210
Is connected to each base station controller 208 or is built in
Each protocol unit 210 includes a GPRS support node (SGSN) 21
2 functions as an interface. GPRS support node 212
Acts as an interface to the packet data network 214. The base station controller 208 is connected to the mobile switching center 102 through the A interface 215. The mobile switching center 202 is connected to the circuit switching network 21.
6 functions as an interface. The SGSN 212 may also connect to other SGSNs belonging to other service providers, which may
N can also connect to other SGSNs.

Mobile stations 218, such as wireless telephone devices, communicate with the base stations associated with each base station controller 208 to maintain communication with other mobile stations, circuit switched network 216, and packet data network 214. Can communicate. The mobile station 218 includes a transceiver 220 for transmitting signals to and receiving signals from the base station controller 208, and a processor 220 for processing signals transmitted to or received from the base station controller 208. SGS
N212 tracks the location of mobile station 218 and provides security features and access control. Although only one mobile station 218 is shown in FIG.
There may be more than one mobile station in 00 at a time.

FIG. 4 is a signal flow diagram illustrating signal communication paths within the communication network of the present invention. As shown in FIGS. 3 and 4, when the mobile station 218 first performs a packet data transfer, the current packet data transfer is a temporary block stream (see line 224 in FIG. 4). TBF). Therefore, the mobile station 218 performs packet data exchange through the SGSN 212 in the packet transfer mode.
When the mobile switching center 202 receives the circuit switching information addressed to the same mobile station 218 from the circuit switching network 216, the mobile switching center 202 notifies the base station controller 208 of the circuit switching information including the intended mobile station 218. Therefore, a circuit-switched paging message is sent to the base station controller 208 through the A interface 215, as shown by line 226. Target mobile station 218 class
Based on the mark, the base station controller 208 determines whether the mobile station 218 supports the dual transfer mode. Further, the base station controller 208
Also determines if the mobile station 218 is currently located in the temporary block stream.

In the present invention, the base station controller 208 determines that the mobile station 218 does not support the dual transfer mode, and also determines that the mobile station 218 is not currently in a temporary block flow. If so, the circuit switched message is sent to the mobile station 218 over the current paging channel.

However, in the present invention, when the base station controller 208 determines that the mobile station 218 supports the dual transfer mode and the mobile station 218 is currently in a temporary block flow. Is the base station controller 208 on line 228
The message is sent to the protocol control unit 210 as shown by. Next, the protocol control unit 210 is notified that the circuit-switched page is pending for the identified mobile station 218, and the protocol control unit 210 is notified to the radio resource (RR) layer of the mobile station 218 to control the radio link. Instructs the circuit switched paging message in the (RLC) control block to be sent. The protocol control unit 210 then sends a radio link control / medium access control (RLC / MAC) control block to the base station controller 208, which, as indicated by line 230, transmits the packet data channel. The RLC / MAC control block is transmitted to the mobile station 218 by inserting the RLC / MAC control block in one block of the multi-frame structure of 52 frames. The inserted RLC / MAC control block indicates to the mobile station 218 that the destination mobile station is currently circuit-switched paged. In the case of the present invention, for example, RL
The C / MAC control block informs the mobile station 218 that the circuit switched paging message is a block B0-B of the packet data channel multiplex frame 100 of FIG.
Notify that it may be included in any of 11.

If the transceiver 222 of the mobile station 218 receives an RLC / MAC control block that informs the mobile station that it is circuit-switched paging, the processor 220 of the mobile station 218 determines the RLC / MAC control block. And determines that the mobile station 218 is circuit-switched paging. As a result, the mobile station 218 aborts its current packet data transfer and starts monitoring the combined control channel with random access. That is, mobile station 218 is currently in idle mode and establishes circuit-switched voice switching activity according to a well-known signaling sequence, as shown by line 232 in FIG. The combined control channel can also be used to exchange signaling information to set up simultaneous voice and data channels with dual mode transfer requirements. Doing so allows mobile station 218 to continue the previously interrupted packet data transfer and obtain the circuit switched voice session. Preferably, the user channels are 1/2 of the traffic channels and 1/2 of the packet data channels (TCH
/ H + PDCH / H). If desired, one or more adjacent packet data channels (TCH) for all traffic channels.
/ F + PDCH / F) can be included.

Upon completion of the above signal flow corresponding to lines 226-232 of FIG. 4, data is immediately available in the form of circuit switched data between mobile switching center 202 and mobile station 218, as indicated by line 234. Will be replaced. As shown by line 234, SGSN21
Data is immediately exchanged between the mobile station 218 and the mobile station 218 in the form of packet switched data. As such, mobile station 218 is operating in simultaneous voice and user packet data sessions.

FIG. 5 is a flow chart of a communication network mechanism for notifying a mobile station of the circuit switched paging message of the present invention. As shown in FIG. 5, after the base station controller receives a circuit switched paging message from the circuit switched area from the mobile switching center in step 300, the base station controller determines in step 310 the mobile station class. -The mark determines whether the mobile station can operate in the dual transfer mode. If the base station controller determines that the mobile station cannot operate in the dual transfer mode, then a circuit switched paging message is sent to the mobile station over the paging channel (PGCH) in step 320.

If the base station controller determines in step 310 that the mobile station can operate in the dual transfer mode, the base station controller determines in step 330 that the mobile station is currently performing packet switched data exchange activity. Determine whether or not If the base station controller determines in step 330 that the mobile station is not currently performing packet switched data exchange activity, then in step 320 the circuit switched paging message is sent to the mobile station over the paging channel (PGCH). Sent. On the other hand, if the base station controller determines in step 330 that the mobile station is currently performing packet switched data exchange activity, the base station controller informs the protocol control unit which mobile station is currently paged. In step 340, the protocol control unit sends the RLC / MAC control block to the mobile station in a block of the packet data channel multiplex frame.

Upon receiving the RLC / MAC control block, the mobile station realizes that it is paging and aborts its current packet data transfer, and in step 350, due to the dual transfer mode requirement, the voice channel and data are transferred. Starts monitoring of the combined control channel with random access to set up a circuit switched voice connection which can include a user data channel, along with an assignment to the channel.

The signaling of the present invention results in the creation of simultaneous voice and data sessions, allowing the mobile station to continue interrupted packet data transfers and obtain circuit switched voice sessions. Thus, the present invention provides a mechanism for a mobile station to receive and process paging messages from the circuit switched area while exchanging data in the packet switched area.

While we have shown and described specific embodiments of the present invention, various modifications can be made to the invention. Therefore, the appended claims are to encompass all such changes and modifications as fall within the true spirit and scope of this invention.

[Brief description of drawings]

FIG. 1 is a conceptual diagram showing an outline of a communication network of a GPRS system.

FIG. 2 is a conceptual diagram outlining a multiple frame structure for a packet data channel and a joint control channel.

FIG. 3 is a conceptual diagram showing an outline of a communication network of the present invention.

FIG. 4 is a flow chart of signals on a signal communication path in the communication network of the present invention.

FIG. 5 is a flow chart of a mechanism for informing a mobile station of a packet switched paging message of the present invention.

─────────────────────────────────────────────────── ─── Continued front page    (81) Designated countries EP (AT, BE, CH, CY, DE, DK, ES, FI, FR, GB, GR, IE, I T, LU, MC, NL, PT, SE, TR), OA (BF , BJ, CF, CG, CI, CM, GA, GN, GW, ML, MR, NE, SN, TD, TG), AP (GH, G M, KE, LS, MW, MZ, SD, SL, SZ, TZ , UG, ZW), EA (AM, AZ, BY, KG, KZ, MD, RU, TJ, TM), AE, AG, AL, AM, AT, AU, AZ, BA, BB, BG, BR, BY, B Z, CA, CH, CN, CR, CU, CZ, DE, DK , DM, DZ, EE, ES, FI, GB, GD, GE, GH, GM, HR, HU, ID, IL, IN, IS, J P, KE, KG, KP, KR, KZ, LC, LK, LR , LS, LT, LU, LV, MA, MD, MG, MK, MN, MW, MX, MZ, NO, NZ, PL, PT, R O, RU, SD, SE, SG, SI, SK, SL, TJ , TM, TR, TT, TZ, UA, UG, UZ, VN, YU, ZA, ZW (72) Inventor Otting, Masha             United States 60060 Ma, Illinois             Ndeline North Lincoln Aveni             View 246 F term (reference) 5K030 HA02 HA08 HA14 HB01 HB18                       JT09                 5K067 CC08 DD53 DD54 DD57 EE04                       EE10 EE16 EE23 JJ12 JJ15

Claims (20)

[Claims] 1. A method for determining the capability of a mobile station, transmitting a control block for notifying the mobile station of a circuit-switched paging message, and for setting simultaneous voice and packet-switched data switching activity. Providing a signaling path using a joint control channel for the mobile station and the base station to exchange signaling information, the method for signaling a circuit switched paging message to a mobile station in dual transfer mode. 2. The method of claim 1, wherein the control block is inserted in a packet data channel corresponding to the packet switched data switching activity. 3. The method of claim 2, wherein the control block is a radio link control / medium access control block. 4. Terminating said packet-switched data exchange activity; monitoring said bonded control channel to establish circuit-switched voice exchange activity; operable in duplex transfer mode, at which time packet Responsive to the mobile station undergoing an exchange data exchange activity, providing simultaneous voice and data transmissions in a duplex transfer mode. 5. Sending the circuit switched paging message over a paging channel in response to the mobile station incapable of operating in a dual transfer mode, and wherein the packet switching data switching activity is not currently being performed. Sending the circuit-switched paging message over the paging channel in response to a mobile station. 6. The method of claim 5, wherein the simultaneous voice and data transmissions occur over channels that include 1/2 of the traffic channel and 1/2 of the packet data channel. 7. The method of claim 5, wherein the simultaneous voice and data transmissions occur over channels including a full traffic channel and one or more adjacent packet data channels. 8. A step of determining whether the mobile station is capable of operating in a dual transfer mode, a step of determining whether the mobile station is currently performing packet switched data exchange activity, and Transmitting a control block notifying the mobile station of a circuit-switched page in response to the mobile station which is operable in a heavy transfer mode and is currently performing packet-switched data exchange activity; The circuit to the mobile station consists of aborting the data exchange activity, monitoring the combined control channel set up for the circuit-switched voice exchange activity, and performing simultaneous voice and data transmission in duplex transfer mode. How to notify the exchange page. 9. The method of claim 8, wherein the control block is inserted in a packet data channel corresponding to the packet switched data exchange activity. 10. The method of claim 8, wherein the control block is a radio link control / medium access control block. 11. A step of transmitting the circuit switched paging message over a paging channel in response to the mobile station being inoperable in duplex transfer mode, the packet switching data switching activity being performed at that time. Sending the circuit-switched paging message over the paging channel in response to the mobile station not present. 12. The method of claim 11, wherein the simultaneous voice and data transmissions occur over channels that include 1/2 of the traffic channel and 1/2 of the packet data channel. 13. The method of claim 11, wherein the simultaneous voice and data transmissions occur over channels including a full traffic channel and one or more adjacent packet data channels. 14. A transceiver that receives a control block that notifies a circuit-switched paging message to the mobile station in response to a base station that receives a circuit-switched page addressed to the mobile station, the mobile station and the base station. A processor that processes the control block using a combined control channel through which the mobile station and base station exchange signaling to set up simultaneous circuit-switched voice and packet-switched data switching activity and provides a signaling path; A mobile station for transmitting and receiving signals from a base station controller of a communication system. 15. The processor, in response to receiving the control block, instructs the mobile station to abort the packet data exchange, is operable in a dual transfer mode, and is at that time a packet exchange data exchange activity. 15. Instructing the mobile station performing an indication to monitor the combined control channel to set up circuit switched voice exchange activity for simultaneous voice and data transmissions in a duplex mode in response to the mobile station performing the transmission. The listed mobile station. 16. The mobile station of claim 15, wherein the control block is inserted in a packet data channel corresponding to the packet switched data exchange activity. 17. The mobile station according to claim 16, wherein the control block is a radio link control / medium access control block. 18. The mobile that transmits the circuit-switched paging message over a paging channel in response to the mobile station incapable of operating in a dual transfer mode, without any packet-switched data switching activity at that time. The mobile station of claim 17, wherein the circuit switched paging message is transmitted over the paging channel in response to the station. 19. The mobile station of claim 18, wherein the simultaneous voice and data transmissions occur over channels including 1/2 of a traffic channel and 1/2 of a packet data channel. 20. The method of claim 18, wherein the simultaneous voice and data transmissions occur over channels including a full traffic channel and one or more adjacent packet data channels.