EP0737407A1

EP0737407A1 - Power saving method for a mobile radio terminal

Info

Publication number: EP0737407A1
Application number: EP95935999A
Authority: EP
Inventors: Eric Desorbay
Original assignee: Alcatel CIT SA; Alcatel Mobile Communication France SA
Current assignee: Alcatel CIT SA
Priority date: 1994-10-24
Filing date: 1995-10-23
Publication date: 1996-10-16
Also published as: FI962541A0; AU3809295A; FR2726147A1; FI962541A; WO1996013134A1; FR2726147B1; CA2179662A1; JPH09512407A

Abstract

A power saving method for a mobile terminal receiving a data message from a mobile radio network, said data message consisting of a series of N blocks (BL) of which only the first M blocks contain useful data, N being a predetermined integer while M is an integer between 1 and N depending on said data message. According to the method, information (b1; b1, b2) indicating the number M of useful data blocks in the message is transmitted in said data message by the mobile network, and the mobile terminal is deactivated when said information (b1; b1, b2) has been read out by the mobile terminal and after the first M blocks containing useful data have been received.

Description

Energy saving method in a mobile radiocommunication terminal

The present invention relates to an energy saving method in a mobile terminal receiving, from a mobile radiocommunication network, a data message which is formed by N successive blocks among which only M first blocks are occupied by data. useful, N and M being integers, and M being less than N. It also relates to a mobile terminal for implementing the method. The invention applies, for example, to a digital cellular radio network, as defined by the GSM (Global System for Mobile communication) Recommendations. Within the framework of GSM, the transmission on radio channel between mobile terminal and mobile network is organized in successive frames, each having a duration of 120/26 ms and comprising 8 time intervals, or windows, intended to receive "bursts", which can be data bursts, speech bursts, etc. These frames are organized into superframes each comprising 1326 frames, and defining a duration of 1326. (120/26) ms, or 6.12 s. The superframes are associated in hypertra es of 2048 superframes, each hyperframe having a duration of (2048.6.12) s = 3 h 28 min 53 s 760 s. Each superframe of 1326 frames is organized according to one of two different patterns which are either a pattern of 51 multiframes-26 per superframe, or a pattern of 26 multiframes-51 per superframe. A multiframe-26 has 26 frame time slots, and a multiframe-51 has 51 frame time slots. Multi-frames define the logical, not temporal, organization of data in channels. Thus, two successive time intervals of the same frame can belong one to a multiframe-51 and the other to a multiframe-26. In practice, each multiframe- P, with P = 26 or 51, is composed of P time intervals of the same rank respectively in P successive frames. These different frame times, multiframe, superframe and hyperframe are used to unwind program sequences. For example, hyperframe corresponds to the cycle of frequency hopping laws in frequency hopping technique.

Referring to Figures 1A and 1B show two successive multiframes-51 associated to typical format for GSM, which are transmitted from the mobile network to ^'mobile terminals. Each multiframe-51 represented comprises 51 time intervals, each intended to convey a burst which defines alone or in combination with other bursts, a channel. The channels defined in the two multiframes-51 represented are 8 dedicated control channels 8.T1, 8.T2, 8.T3, 8.T4, 8.T5, 8.T6, 8.T7 and 8.T8 (SDCCH for Stand-alone Dedicated Control CHannel in English terminology, and also called TCH / 8), and 8 associated slow control channels 4.SI, 4.S2, 4.S3, 4.S4, 4.S5, 4.S6 , 4.S7 and 4.S8 (SACCH for Slow Associated Control CHannel), 6 time intervals X remaining unoccupied. Each dedicated control channel 8.Ti, i comprised between 1 and 8, is defined by a cycle of 8 time intervals, denoted Ti, every 2 multitrames 51, first 4 time intervals Ti of the B.Ti channel belonging to the first multiframe-51 and 4 other time intervals Ti belonging to the second multiframe-51. Each associated slow control channel 4.Si, i between 1 and 8, is defined by a cycle of 4 time intervals If all the 2 multiframes-51, belonging either to the first multiframe-51 or to the second multiframe- 51. The role of each of these channels will not be described in more detail and reference may usefully be made to the work "The GSM System for Mobile Communication" produced and published by M. MOULY and MB PAUTET, Edition 1994. In the following description, our attention will be focused only on the dedicated control channels 8.T1 to 8.T8. These channels can be used, in addition to their main role of transmitting dedicated signaling messages, to convey data message broadcasting channels (CBCH for Cell Broadcast CHannel in English terminology). A data message broadcast channel CBCH, or 4.Ti, then occupies half of the time intervals Ti of the corresponding dedicated control channel β.Ti, or four time intervals Ti per pair of multiframes-51. These data messages are short messages, for example intended to be displayed on a screen of the mobile radiocommunication terminal. By way of example, in FIG. 2 is shown a data message broadcasting channel 4.T8 formed by four successive time intervals T8 in the first multiframe-51 of FIG. 1A. In the four time intervals T8, four respective bursts B1, B2, B3 and B4 are transmitted by a mobile network base station. Each of the bursts B1 to B4 is framed by data from the header and from the end of the burst TB. The four bursts B1 to B4 form a block and a data message comprises N = 4 blocks. Typically according to the prior art, the mobile terminal is informed beforehand of the subsequent broadcast of a data message from a predetermined instant corresponding to the start of the first of the four time intervals T8 which transport the first block in the data message which is formed by N = 4 blocks. A data message results from the association of 4 blocks or 4.4 = 16 bursts. At this predetermined instant, the terminal, assumed to have previously been put on standby, reactivates almost all of the circuits which compose it to receive the binary content transported in the N = 4 blocks. Regardless of the length of the data message and therefore, depending on the message, the number of blocks, which can vary from M = l to M = 4, which are filled with useful data, the mobile remains activated to receive the N = 4 blocks, which defines an activation duration of sixteen bursts. In practice, if M first blocks convey useful data from the data message, the last (NM) blocks remaining, with N = 4 in the embodiment described, contain stuffing data. Thus, according to the prior art, it follows that the reception by the mobile terminal of a data message induces an unnecessary consumption of energy when the number of blocks transporting useful data is less than the number of blocks, here assumed to be equal to N = 4, forming the data message.

A first objective of the invention is to remedy the aforementioned drawback by providing an energy saving method in a mobile terminal receiving, from a mobile radiocommunication network, a data message which is formed by N successive blocks among which only M first blocks are occupied by useful data.

Another objective of the invention is to provide a mobile terminal for the implementation of the method

To this end, an energy saving method in a mobile terminal receiving, from a mobile radiocommunication network, a data message which is formed by N successive blocks among which successive blocks only M first blocks are occupied by useful data, N being a predetermined integer, and M being an integer which is between l and N as a function of said data message, is characterized in that it comprises the steps of: - transmission by the mobile network in said data message, of indication information representative of the number M of useful data blocks in said message, and

- As a result of the mobile terminal reading said information, putting the mobile terminal to sleep after receiving said M first blocks occupied by useful data. According to a first variant of the invention, the indication information is conveyed in a very first block of said M first useful data blocks, and indicates the number M of first useful data blocks, and the standby of the mobile terminal is effective after reception of a number of blocks equal to the number M which is indicated by said indication information, from said very first block.

According to a second variant of the invention, the indication information is conveyed in the first M blocks of useful data, and indicates in each of said M first blocks, the existence or the lack of existence of a first following block useful data, and standby is effective after complete reception of said each of the M blocks, as soon as said indication information indicates the absence of existence of a first next block of useful data.

Typically, the mobile network is a cellular digital network of the G.S.M. type, and the data message is conveyed in a broadcasting subchannel of a dedicated control channel.

A mobile radiocommunication terminal according to the invention for implementing the method according to the first variant further comprises a central processing unit, radio transmission and reception means and peripheral means. It is characterized in that the central unit comprises means for reading said indication information indicating the number M of useful data blocks, and means for putting the mobile terminal to sleep after a duration corresponding substantially to the duration of M blocks of useful data, counting from the time of the start of reception of the very first of said M first blocks.

A mobile radiocommunication terminal according to the invention for implementing the method according to the second variant further comprises a central processing unit. processing, radio transmission and reception means and peripheral means. It is characterized in that the central unit comprises means for reading said indication information indicating the existence or the absence of existence of a first block following useful data in each of said first blocks, and means for putting on standby the mobile terminal after complete reception of a first block of useful data which includes indication information indicating the lack of existence of a first next block of useful data.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description with reference to the corresponding appended drawings in which:

FIGS. 1A and 1B, already commented on, show two respective multiframes, called multiframes-51, transmitted from a mobile network to a mobile terminal in a cellular radiocommunication network with mobiles of the GSM type, and associated with each other to form dedicated control channels;

FIG. 2, also already commented on, shows a subchannel of a dedicated control channel, which is intended to convey, from a mobile network to a mobile terminal, a block of data among N = 4 blocks of data in a data message;

- Figure 3 shows in detail the binary structure of a data block to explain the implementation of the method according to the invention; and - Figure 4 is a block diagram of a mobile terminal for the implementation of the method of the invention.

With reference to FIG. 3, each of the N = 4 BL blocks formed from four bursts Bl, B2, B3 and B4 comprises one byte of information INFO, denoted ol, and 22 bytes o2 to o23 of data, useful or of stuffing, DATA. In the byte of information ol, two bits convey link protocol discrimination information LPD (Link Protocol Discriminator in English terminology), four bits carry sequence number information SEQ, and two bits bl and b2 are free. The two LPD bits are used in the terminal to activate one of 2 ² protocol layers, relative to the OSI (Open System Interconnection) architecture of the ISO (International Standardization Organization), through which the data message is received. . The four SEQ bits are used for chaining purposes in the terminal of received data messages.

The invention provides for using the two free bits b1 and b2 to implement the method of the invention, two variants being provided.

According to a first variant, it is proposed that the two free bits b1 and b2 of the very first block BL among the N = 4 blocks are used to transmit information indicating the number M of first blocks carrying useful data. This indication information is sent by the mobile network in burst bits corresponding to bits b1 and b2 in the block. For example, the correspondence between the binary value taken by the bits bl and b2 and the associated meaning can be as follows: - If bl = "0" and b2 = "0", then the data message includes M = 4 useful data blocks,

- If bl = "0" and b2 = "l", then the data message includes M = l useful data blocks,

- If bl = "l" and b2 = "0", then the data message includes M = 2 useful data blocks, and

- If bl = "l" and b2 = "l", then the data message includes M = 3 useful data blocks. Referring to Figure 4, there is shown a mobile radio terminal 1 for the implementation of the invention. The terminal 1 comprises a central processing unit 10 associated with an activity controller 10a, a radio transmission and reception unit 11 connected to an antenna 1a and peripheral circuits 12 and 13, such as keyboard, SIM card reader, etc. The central unit 10 receives, through a data bus BD coming from unit 11, the information byte ol included in the very first block BL of the N = 4 blocks and reads the bits bl and b2 indicating the number M of useful data blocks. As a result of this reading, the unit 10 and controller 10a cooperate to put the mobile terminal to standby after a duration corresponding substantially to the duration of M useful data blocks, from the moment of the start of reception of the very first of the M blocks. Thus, the terminal 1 is put on standby after reception of a number of blocks equal to the number M which is indicated by the information constituted by the two bits bl and b2. Typically, the terminal is put into standby as follows. The central processing unit 10 sends a deactivation message ME, through an interface, represented by an arrow in broken lines, to an input of the controller 10a. The controller 10a, on receipt of the message ME, and, as a function of this message, puts the radio telephone 1 in total or partial standby. For this, in particular, it deactivates some or all of the clock circuits producing the clock signals CK clocking the digital circuits, and triggers timers whose function is to reactivate at the expiration of a predetermined period these clock circuits which are deactivated.

According to a second variant, it is proposed that, in each of the first M blocks intended for carrying useful data, one of the two free bits bl and b2 in the byte ol transmits information indicating the existence or the failure of existence of a next block of useful data. This information is produced and transmitted by the mobile network in a bit of one of the four bursts forming the block, corresponding to said free bit. For example, the free bit bl is used for this purpose, and the correspondence between the binary value taken by the bit bl and the associated meaning can be as follows:

- If bl = ^w 0 ", then there is a next block of useful data, - If bl =" l ", then there is no next block of useful data.

The mobile radiocommunication terminal for implementing this second variant is substantially identical to the terminal described with reference to FIG. 4 for the first variant. It differs from this by the fact that the central unit 10 reads in each block the bit bl indicating the existence or the lack of existence of a next block of useful data, and puts on standby, in cooperation with the controller 10a, the mobile terminal after complete reception of a block of useful data which includes a bit bl indicating the lack of existence of a next block of useful data. Thus, the mobile terminal is kept activated and put on standby after complete reception of a block of useful data, respectively depending on whether the indication bit bl indicates the existence and the failure of existence of a next block of useful data .

According to the two aforementioned variants, it is expected that the mobile network transmits in a data message, here formed of N = 4 BL data blocks, an indication information representative of the number M of useful data blocks in the message. In the first variant, this indication information is conveyed by the bits b1 and b2 in the first block of the message. In the second variant, this indication information is conveyed by the bits b1 transmitted in the M useful data blocks. According to these two variants, as a result of the reading by the mobile terminal 1 of this indication information, the terminal is put on standby after reception of the M first blocks occupied by useful data.

Claims

CLAIMS:

1 - Method for saving energy in a mobile terminal (1) receiving, from a mobile radiocommunication network, a data message which is formed of N successive blocks (BL) among which successive blocks only M first blocks are occupied by useful data, N being a predetermined integer, and M being an integer which is between 1 and N depending on said data message, characterized in that it comprises the steps of:

- transmission by the mobile network in said data message, of indication information (bl; bl, b2) representative of the number M of useful data blocks in said message, and

- As a result of the reading by the mobile terminal (1) of said information (bl, b2), putting the mobile terminal (1) to sleep after reception of said M first blocks occupied by useful data.

2 - Method according to claim 1, characterized in that said indication information (b1, b2) is conveyed in a very first block of said M first useful data blocks, and indicates the number M of first useful data blocks, and in that said standby of the mobile terminal (1) is effective after reception of a number of blocks equal to the number M which is indicated by said indication information (b1, b2), from said very first block.

3 - Method according to claim 1, characterized in that said indication information (bl) is conveyed in the first M blocks, and indicates in each of said first M blocks, the existence or the lack of existence of a first next block of useful data, and in that said standby is effective after complete reception of said each of the M blocks, as soon as said indication information indicates the lack of existence of a first next block of useful data.

4 - Method according to any one of claims 1 to 3, characterized in that said mobile network is a digital cellular network of GSM type, and in that said data message is conveyed in a broadcast subchannel of a dedicated control channel.

5 - mobile terminal (l) for implementing the method according to claim 2, further comprising a central processing unit (10), radio transmission and reception means (11) and peripheral means, characterized in that said central unit (10) comprises means for reading said indication information indicating the number M of useful data blocks, and means (10, 10a) for putting the mobile terminal into standby after a duration corresponding substantially to the duration of M blocks of useful data, counting from the instant of start of reception of the very first of said M first blocks.

6 - mobile terminal for implementing the method according to claim 3, further comprising a central processing unit (10), radio transmission and reception means (11) and peripheral means, characterized in that said central unit (10) comprises means for reading said indication information indicating the existence or the absence of existence of a first block following useful data in each of said first blocks, and means (10, 10a) for putting on standby the mobile terminal after complete reception of a first block of useful data which includes indication information indicating the lack of existence of a first next block of useful data.