FR2911237A1 - Information transmitting method for telecommunication terminal, involves inserting value of word in control message field, and transferring message, where number of values in set of values is less than number of values that word considers - Google Patents

Abstract

The method involves obtaining a value of a word among a set of values, during allocation of a given sub-set of resources of a telecommunication interface at a telecommunication terminal. A value of the word different from each value of the set of values is obtained, when information non representative of an allocation of the given set of resources is transferred. The value of the obtained word is inserted in a field of a control message, where the number of values in the set of values is lesser than the number of values that the word considers. The control message is transferred. Independent claims are also included for the following: (1) a method for receiving information transmitted by a base station (2) a base station comprising an obtaining unit (3) a telecommunication terminal comprising a determining unit (4) a computer program comprising a set of instructions to perform a method for transmitting information (5) a computer program comprising a set of instructions to perform a method for receiving transmitted information.

Description

The present invention relates to a method and a transfer device

  information from a base station to a telecommunication terminal on at least one resource of a telecommunication interface according to which the base station and the telecommunication terminal are connected.

  Conventionally, in telecommunication systems such as for example the UMTS system, an acronym for Universal Mobile Telecommunications System, a base station must transfer to telecommunications terminals multiple information such as control commands. These control commands are conventionally transferred via a common resource, or common physical channel such as for example the HS-SCCH channel, acronym for High Speed Shared Control Channel described in the standard 3GPP TS 25.212 version 7.2.0. The HS-SCCH is a common physical control channel that has been defined to dynamically allocate physical traffic channels to at least one telecommunication terminal present in the base station cell. At each introduction of a new feature in a telecommunication network, it may be necessary to create new control commands. For example, it has been proposed to introduce into the UMTS system the possibility of initiating or stopping the discontinuous transmission of data on the physical channel UL DPCCH, acronym for UpLink Dedicated Physical Control CHannel, and the discontinuous reception of physical channels. downlink. The telecommunication network may, after configuring this feature to a mobile terminal, independently enable or disable the discontinuous transmission mode of the UL DPCCH physical channel or the discontinuous reception mode of the downlink physical channels by a control command. It has been proposed to insert this control command in the already existing HS-SCCH physical channel so as not to use additional resources. For this, it has been proposed to reserve the value 111101 of the transport size information field for this control command. This proposal is described in the documents referenced in the report RP-060728 available at: ftp://ftp.3gpp.org/tsg_ran/TSG RAN / TSGR 34 / Docs / RP-060683.zip, and in particular in R1-063014 available at ftp://ftp.3gpp.org/tsg ran / WG 1 RL 1 / TSGR 1 46bis / Docs / R 1-063014.zip. 2 This proposal is not satisfactory. Indeed, the number of values that the Transport-block size information field can take is reduced by one value. Its use is therefore restricted. In addition, the Transport-block size information field is only available when the HS-SCCH physical channel has been fully decoded.

  The real-time constraints that the telecommunication terminal must assume become difficult to ensure. The invention aims to solve the disadvantages of the prior art by proposing a method and a device for transferring information that does not significantly increase the real-time constraints that the telecommunications terminal must assume while avoiding to restrict the use of a field of a message conveyed by a resource, and while avoiding to use an additional resource. For this purpose, according to a first aspect, the invention proposes a method of transferring information from a base station to a telecommunication terminal on at least one resource of a telecommunication interface according to which the station is connected. base and the telecommunication terminal, the information being transmitted in a field of a control message, the field comprising a word, characterized in that the method comprises the steps performed by the base station: -obtaining, when allocating a given subset of other resources of the telecommunication interface to the telecommunication terminal, a value of the word among a set of values, the number of values included in the set of values being less than the number of values that the word is likely to take, each value of the set being representative of the allocation to a telecommunication terminal of a given subset of other resources s of the telecommunication interface, - obtaining a value of the word different from each value of the set of values if information not representative of an allocation of a given set of other resources is transferred, - insertion of the value of the word obtained in the field of the control message; transfer of the control message. Correlatively, the present invention relates to a base station able to transfer information to a telecommunication terminal on at least one resource of a telecommunication interface according to which the base station and the telecommunication terminal are connected, the information being transmitted. in a field of a control message, the field comprising a word, characterized in that the base station comprises: means for obtaining, when allocating a given subset of other resources of the telecommunication interface to the telecommunication terminal, a value of the word from among a set of values, the number of values included in the set of values being less than the number of values that the word is likely to take, each value of the set being representative of the allocation to a telecommunication terminal of a given subset of other resources of the telecommunication interface, - means for obtaining a value of the word different from each value of the set of values if a non-representative information of an allocation of a given set of other resources is transferred, - means for inserting the value of the word obtained in the field of the control message, - transfer means of the control message. The inventors of the present invention have noted that the number of values in the set of values is less than the number of values that the word is likely to take. The present invention takes advantage of this feature to use the conventionally defined field for allocating a subset of other resources for other purposes. Thus, it is avoided to restrict the use of a field of a message conveyed by a resource. According to a particular embodiment of the invention, the field is included in a header of the control message.

  Thus, it is not necessary to decode the entire control message to obtain this information. This is all the more interesting as the header of the control message is coded separately from the rest of the message. The real-time constraints that the telecommunication terminal must assume remain acceptable. According to a particular embodiment of the invention, the other resources of the telecommunication interface are numbered and if at least two other resources are allocated to a telecommunication terminal, the resources have consecutive numbers and each value representative of the allocation to a telecommunication terminal of a given subset of other resources of the telecommunication interface is obtained from the number of another resource allocated to the telecommunication terminal and the number of other resources allocated to the telecommunication terminal . Thus, the other resources are represented by a reduced number of bits. According to a particular embodiment of the invention, the value of the field is broken down into a first and a second sub-value. The first sub-value is obtained from the number of other resources allocated to the telecommunication terminal and the second sub-value is obtained from the number of other resources allocated to the telecommunication terminal and the number of the other resource having the smallest number among the numbers of the other resources allocated to the telecommunication terminal. Thus, the determination of the other resources by the telecommunication terminal from the value of the word is done simply. According to a particular embodiment of the invention, the word consists of a first and a second subword, the first subword having three bits, the second subword comprising four bits. The first subvalue is computed according to the following formula: xa.s, l, xecs, z, xc, s, 3 = min (P û 1.15-P) where xces ,,, xc, s, 2, xccs , 3 are respectively the first, second and third bits of the first subword, min (x, y) represents the minimum value of the elements of the pair (x, y), P is the number of other resources allocated to the terminal of telecommunication and 15 is the total number of other resources of the telecommunication interface. The second sub-value is calculated according to the following formula: xe, 4, xccs, 5, xccs, 6, xccs, 7 = 10 -10 LP / 8 J * 151 where x, cs ,,, x, cs, 5, xecs, 6, xccs, 7 are respectively the first, second, third and fourth bits of the second subword, 1x1 represents the absolute value of x, Lx] 25 represents the integer part of x and O is the number of the other resource with the lowest number among the numbers of the other resources allocated to the telecommunication terminal. Thus, the determination of the other resources by the telecommunication terminal from the value of the word is done simply. According to a particular embodiment of the invention, the telecommunication interface is a telecommunication interface using a code division multiple access method and the information that is not representative of an allocation of a given subset of data. other resources includes a first signaling sub-information of the transmission of a command for the telecommunication terminal. Thus, the telecommunication terminal quickly determines whether the value of the word is representative of an allocation of other resources or representative of another command. According to one particular embodiment of the invention, the first signaling sub-information of the transmission of a command intended for the telecommunication terminal is represented by the binary sequence 1110. Thus, the telecommunication terminal quickly determines whether the value of the word is representative of an allocation of other resources or representative of another order. According to a particular embodiment of the invention, the information that is not representative of an allocation of a given subset of other resources comprises a second sub-information identifying the type of command intended for the telecommunication terminal. Thus, the value of the word can be representative of a plurality of commands. According to a particular embodiment of the invention, the command is a command authorizing the discontinuous transmission of the telecommunication terminal to the base station on at least one other resource of the telecommunication interface or the discontinuous reception of the base station. to the telecommunication terminal on at least one other resource of the telecommunication interface. Thus, it is not necessary to decode the entire control message to obtain this information as proposed by the state of the art. According to a second aspect, the invention proposes a method of receiving information transmitted by a base station to a telecommunication terminal on a resource of a telecommunication interface according to which the base station and the terminal of the telecommunication terminal are connected. telecommunication, the information being transmitted in a field of a control message, the field comprising a word, characterized in that the method comprises the steps performed by the telecommunication terminal 30 of: - receiving at least the message field of the message control, - determining whether the value of the word included in the field is representative of the allocation to the telecommunication terminal of a given subset of other resources or if the value of the word included in the field is not representative an allocation of a given set of other resources. Correlatively, the invention relates to a telecommunication terminal able to receive, from a base station, information transmitted on a resource of a telecommunication interface according to which the base station and the telecommunication terminal are connected, the information being transmitted in a field of a control message, the field comprising a word, characterized in that the telecommunication terminal comprises: means for receiving at least the field of the control message; means for determining whether the value the word included in the field is representative of the allocation to the telecommunication terminal of a given subset of other resources or if the value of the word included in the field is not representative of an allocation of a set given other resources. Thus, the word included in the classically defined field for the allocation of a subset of other resources is used for other purposes. According to a particular embodiment of the invention, the information that is not representative of an allocation of a given subset of other resources includes a first information sub-information signaling the transmission of a command intended for the telecommunication terminal.

  Thus, the telecommunication terminal quickly determines whether the value of the word is representative of an allocation of other resources or is representative of another command. According to a particular embodiment of the invention, the information that is not representative of an allocation of a given subset of other resources includes a first information sub-information signaling the transmission of a command intended for the telecommunication terminal. Thus, the telecommunication terminal quickly determines whether the value of the word is representative of an allocation of other resources or representative of another command.

  According to a particular embodiment of the invention, the first signaling sub-information of the transmission of a command intended for the telecommunication terminal is represented by the binary sequence 1110.

  Thus, the telecommunication terminal quickly determines whether the value of the word is representative of an allocation of other resources or representative of another command. According to a particular embodiment of the invention, the information that is not representative of an allocation of a given subset of other resources comprises a second sub-information identifying the type of command intended for the telecommunication terminal. Thus, the value of the word can be representative of a plurality of commands. According to a particular embodiment of the invention, the command is a command authorizing the discontinuous transmission of the telecommunication terminal to the base station on at least one other resource of the telecommunication interface or the discontinuous reception of the base station towards the telecommunication terminal on at least one other resource of the telecommunication interface. The invention also relates to computer programs stored on an information medium, said programs comprising instructions for implementing the methods described above, when they are loaded and executed by a computer system. The characteristics of the invention mentioned above, as well as others, will appear more clearly on reading the following description of an exemplary embodiment, said description being made in connection with the attached drawings, among which: FIG. . 1 represents the architecture of a portion of a telecommunications network in which the present invention is implemented; FIG. 2 is a block diagram of a base station according to the present invention; FIG. 3 is a block diagram of a telecommunication terminal according to the present invention; FIG. 4 represents an algorithm executed by the base station according to the present invention; FIG. 5 represents an algorithm executed by a telecommunication terminal according to the present invention; FIG. 6a shows an example of a control message including information representative of a resource allocation according to the present invention; FIG. 6b represents an example of a control message comprising information that is not representative of a resource allocation according to the present invention; FIG. 7a is an example of the values taken by the torque (O, P) when the telecommunication interface of the base station has fifteen other resources to allocate; Figs. 7b to 7c are a tutorial example of setting the triangle of FIG. 7a substantially in the form of a rectangle.

  FIG. 1 represents the architecture of a portion of a telecommunication network in which the present invention is implemented. The present invention is presented in the context of a wireless radio network type application but the present invention is also applicable in wireless networks of infrared type or in wired networks. In FIG. 1, a base station 20 is connected to two telecommunication terminals 10a and 10b via a telecommunication interface 50. More specifically, the base station 20 is connected to the telecommunication terminals 10a and 10b via of the telecommunication interface 50 described later with reference to FIG. 2. The telecommunication interface 50 is, for example and without limitation, the air interface of a UMTS type cellular radio network in which the CDMA technology, acronym for Code Division Multiple Access is used. The acronym CDMA stands for CDMA, acronym for Multiple Access by 25 Code Distribution. The telecommunication interface 50 has a set of resources allocated by the base station 20 to the telecommunication terminals 10 which are located in the cell, or radio coverage area, of the base station 20. Only two telecommunication terminals 10a and 10b are shown in FIG. 1 for the sake of clarity but a larger number of telecommunication terminals 10 are present in the cell of the base station 20. A resource of the telecommunication interface 50 is, for example, a frequency sub-band and / or a time interval and / or a code. A resource is, in the context of CDMA technology, also called a physical channel. A physical channel is generally defined by a scrambling code, a channelization code, start and end time conditions, a type of modulation and, depending on the type of modulation, a phase.

  According to the present invention, the base station 20 comprises: means for obtaining, when allocating a given subset of other resources of the telecommunication interface 50 to a telecommunications terminal 10a or 10b , a word value from a set of values, the number of values in the set of values being less than the number of values that the word is likely to take, each value of the set being representative of the allocation at a telecommunications terminal 10a or 10b of a given subset of other resources of the telecommunication interface 50, means for obtaining a value of the word different from each value of the set of values, if information not representative of an allocation of a given set of other resources is transferred, means for inserting the value of the word obtained into the field of the header of a control message; means of transferring the message of c ontrol. By way of example, each value representative of the allocation to a telecommunication terminal 10a or 10b of a given subset of other resources of the telecommunication interface 50, is presented by a set of K bits. K bits take 2K possible values and the number of values in the set of values is less than the number of 2K values that the word is likely to take. In another example, each value representative of the allocation to a telecommunications terminal 10a or 10b of a given subset of other resources of the telecommunication interface 50, is presented by a pair (O, P) where O represents the number of a resource and P the number of resources included in the subset of allocated resources. When a subset of resources has two or more resources, they have consecutive numbers. 0 is between OMIN and OMIN + DYN-1 and P is between PMIN and PMIN + DYN-1 where OMIN is the minimum value of O, PMIN is the minimum value of P and DYN the number of values taken by P and O Fig. 7a is an example of the values taken by the pair (0, P) when the telecommunication interface 50 has fifteen other resources to allocate. If each value in the set of values is the natural binary representation of the integer (0-OMIN) + DYNx (P-PMIN) or the integer (P-PMIN) + DYNx (O-PMIN), four bits are needed to represent O and four bits are needed to represent P.

  Eight bits can represent 256 values. Now, in the example of FIG. 7a, the couple (O, P) can only take 120 values. In this case, the unused values may be associated with information that is not representative of an allocation of a given set of other resources. A more economical solution in terms of bits used consists of numbering the 10 valid pairs (O, P) by traversing the triangle of FIG. 7a line by line from top to bottom, each line being traveled from left to right .There are then 120 numbers. The numbers can then be represented on seven bits that can represent 128 values. In this case, the unused values may be associated with information not representative of an allocation of a given set of other resources. Other solutions are also used to reduce the number of bits. The example described in section 4.6.2.3 of TS 25.212 ver 7.2.0 published at ftp://ftp.3gpp.org/Specs/2006-09/Rel-7/25 series / 25212-720 .zip is another. The proposed solution can be schematically represented by placing the triangle of FIG. 7a substantially in the form of a rectangle as shown in Figs. 7b and 7c. Torque values (O, P) represented by small crosses in the dashed frame of FIG. 7b verifying the condition P PMIN + DYN / 2 are moved to the base of the triangle as illustrated by the dashed arrows in FIG. 7b to form a substantially rectangular shape as shown in FIG. 7c. In Figs. 7b and 7c, PMIN = O, DYN = 15. It should be noted here that DYN being odd, P PMIN + DYN / 2 is equivalent to P PMIN + (DYN + 1) / 2 On the abscissa axis, 15 values can be taken by the variable X and on 30 the y-axis, 7 values can be taken by the variable Y. The set of variables X and Y can then be represented on seven bits which can represent 128 values. In this case, the unused values may be associated with information that is not representative of an allocation of a given set of other resources.

  Considering the example of the standard 3GPP TS 25.212 ver 7.2.0, a control message sent on the physical channel HS-SCCH, acronym for High Speed Shared Channel Control Channel includes a seven-bit field Channelization-code-set information, which makes it possible to signal the allocation of resources or physical channels for the transmission of data. According to the example of section 4.6.2.3 of TS 25.212 ver 7.2.0, Y is referred to as code group indicator and is a first subword encoded on three bits, X is referred to as code offset indicator. and is a second subword encoded on four bits.

  The first, second and third bits xccs, 1, xccs, 2, xccs, 3 encoding Y are calculated according to the following formula: xccs,, xccs, 2, xccs 3 = min (P -1, DYN-P) where min ( x, y) represents the minimum value of the pair (x, y), P is the number of other resources allocated to the telecommunication terminal and DYN is the total number of other resources of the telecommunication interface 50.

  The first, second, third and fourth bits xccs4, xccs, 5, xccs, 6, xccs, 7 encoding X are calculated according to the following formula: xccs, 4, xccs, 5, xccs, 6, xccs, 7 = 10 -10 L2P / DYN J * DYNI where lx1 represents the absolute value of x, Lx] represents the integer part of x and O is the number of the other resource with the lowest number among the numbers of the other resources allocated to the telecommunication terminal . When DYN = 15, the first, second and third bits xccs, 1, xccs, 2, xccs, 3 encoding Y are calculated according to the following formula: xccs, l, xccs, 2, xccs, 3 = min (P -1.15-P) The first, second, third and fourth bits x4, xccs 5, xccs, 6, xccs,? coding X are calculated according to the following formula x4, xccs 5, xccs, 6, xccs, 7 = 10 -10 LP / 8d * 151 where 25 xccs, 4 xccs, 5 xccs, 6, xccs,? = 10 -1 L2P / 15i * 151. The area marked 700 of FIG. 7c includes values not taken by the torque (X, Y). These values are advantageously used by the present invention to represent other information than those representative of a resource allocation. The points included in the area 700 correspond to pairs (X, Y) coded in binary notation 1110000, 1110001, 1110010, 1110011, 1110100, 1110101, 1110110 and 1110111 in which the three most significant bits are representative of the value of Y and the four least significant bits are representative of X.

  We will notice here that the four most significant bits of the points included in the zone 700 are all at the binary value 1110. The present invention takes advantage of these four high-order bits as will be explained later. Fig. 2 is a block diagram of a base station according to the present invention. The base station 20 comprises a communication bus 201 to which are connected a central unit 200, a nonvolatile memory 202, a random access memory RAM 203 and transmission and / or reception means 205. It should be noted here that alternatively, the base station 20 consists of a plurality of dedicated integrated circuits which are adapted to implement the method as described with reference to FIG. 4. The non-volatile memory 202 stores programs implementing the invention such as the algorithm which will be described later with reference to FIG. 4. The non-volatile memory 202 is, for example, a flash memory. More generally, the programs according to the present invention are stored in storage means. This storage means can be read by a computer or a microprocessor 200. Via the transmission and / or reception means 205, the control messages comprising the field according to the invention are transferred to the telecommunication terminals 10. For example, the field is included in the header of the control message. By way of example, the transmission and / or reception means 205 are compatible with UMTS technology using CDMA technology. More specifically, the transmission and / or reception means 205 comprise several wireless interfaces, one of which, designated by FDD mode, relates to a terrestrial cellular mobile radio interface using a paired spectrum. FDD is the acronym for Frequency Division Duplex, which means that the frequency plan is split between the transmission link and the transmission downlink. The uplink represents the transfer of data from a mobile terminal 10 to the base station 20. The downlink represents the data transfer from the base station 20 to a mobile terminal 10. FIG. 3 shows a block diagram of a telecommunication terminal according to the present invention.

  The telecommunication terminal 10 comprises a communication bus 301 to which are connected a central unit 300, a non-volatile memory 302, a random access memory RAM 303 and transmission / reception means 305. It should be noted here that, alternatively, the telecommunication terminal 10 consists of several dedicated integrated circuits which are able to implement the method as described with reference to FIG. 5. The non-volatile memory 302 stores the programs implementing the invention such as the algorithm which will be described later with reference to FIG. 5. More generally, the programs according to the present invention are stored in storage means. This storage means can be read by a computer or a microprocessor 300. Via the transmission and / or reception means 305, the control messages are received by the telecommunication terminal 10. Preferably, the transmission means and / or receiving 305 are compatible with UMTS technology. The transmitting and / or receiving means 305 use CDMA technology. More specifically, the transmission and / or reception means 305 comprise several wireless interfaces, one of which, designated by FDD mode, relates to a terrestrial cellular mobile radio interface using a paired spectrum. Fig. 4 represents an algorithm executed by the base station according to the present invention. More precisely, the present algorithm is executed by the processor 200 of the base station 20. It should be noted here that, in the context of an implementation of the present algorithm according to the 3GPP TS 25.212 ver 7.2.0 standard, the present algorithm is executed by the processor 200 for each HS-SCCH physical channel. In step E400, the processor 200 checks whether other resources different from those used for the physical channel HS-SCCH and allocatable via the physical channel HS-SCCH are to be allocated to a telecommunication terminal 10. If Other resources of the telecommunication interface 50 are to be allocated to a telecommunication terminal 10, the processor 200 proceeds to step E401. Otherwise, the processor 200 proceeds to step E405. In step E401, processor 200 selects a subset of resources to allocate to telecommunication terminal 20.

  A resource is, as part of the CDMA technology, also called a physical channel. A physical channel is generally defined by a scrambling code, a channelization code, start and end timing conditions, modulation and, depending on the type of modulation, a phase. In the FDD mode UMTS system the other resources allocatable via the HS-SCCH physical channel are the HS-PDSCH physical channels, acronym for High Speed Pack and Downlink Shared Channel. Other resources included in the subset of other resources have consecutive numbers.

  In the next step E402, the processor 200 obtains the value of the word corresponding to the selected resources. According to the example of section 4.6.2.3 of TS 25.212 ver 7.2.0, the first, second and third bits xccs,, xccs, 2, xecs, 3 are calculated according to the following formula: xccs, l, xccs, 2, xccs, 3 = min (P ù 1.15 ù P).

  The fourth, fifth, sixth and seventh bits xces 4, xccs, 5, xccs, 6, xccs, 7 are calculated according to the following formula: xccs, 4 xccs, 5 9 xccs, 6 9 xccs, 7 = 10 - 1 - LP / 8J * 151. In a variant, the processor 200 uses a correspondence table to determine the value of the word corresponding to the selected resources.

  In the next step E403, the processor 200 inserts the value of the word obtained in the previous step into the field 620 of the control message as represented in FIG. 6a. Fig. 6a shows an example of a control message comprising information representative of a resource allocation according to the present invention.

  The control message as shown in FIG. 6a is for example a control message transmitted in the physical channel HS-SCCH described in 3GPP TS 25.212 version 7.2.0. The physical channel HS-SCCH is a common physical control channel used to dynamically allocate physical traffic channels to at least one telecommunication terminal present in the base station cell. The allocation is made for the period of time. a TTI (Transmission Time Interval), ie 2 milliseconds. The control messages on HS-SCCH physical channels can be transmitted with the same period so that HS-PDSCH physical channels can be allocated continuously. Field 620 is the Channelization-code-set information field described in 3GPP TS 25.212 version 7.2.0. The field 630 includes useful data which are transferred to the same telecommunication terminal 10. The telecommunication terminal receiving the control message transmitted on the HS-SCCHs is addressed according to a 16-bit word UE identitity which is specific to the telecommunication terminal. 10 recipient. The word UE identity is used to perform on the transmission a specific masking of the telecommunication terminal 10, so that only the destination telecommunication terminal 10 is capable of decoding the control message by performing the inverse operation of the specific masking UE. UE is an acronym for User Equipment, synonymous for the 3GPP UMTS community of telecommunication terminal. In the next step E404, the processor 200 controls the transfer of the control message via the sending and / or receiving means 205. The other allocated resources are then used for the transfer of data, for example in the form of of transport blocks on the HS-PDSCH physical channels, acronym for High Speed Physical Downlink Shared Channel, allocated for the downlink by the base station 20 for the telecommunication terminal 10. At the next step E405, the processor 200 checks if further information is to be transmitted to at least one telecommunication terminal 10. If further information is to be transmitted to at least one telecommunication terminal 10, the processor 200 proceeds to step E406. In the opposite case, the processor 200 returns to the step E400 of the present algorithm. The other information is for example and in a non-limiting manner an HS-SCCH order, better known by the term HS-SCCH order, as presented in the technical report 3GPP TR 25.903 v1.2.0 on "Continuous Connectivity for Packet Data Users ", available at: http://ftp.3gpp.org/tsg ran / TSG RAN / TSGR 34 / Docs / RP-060794.zip. An HS-SCCH order will be called a CPC command later. This command allows for continuous packet connectivity. More specifically, this command allows the discontinuous transmission of the UL DPCCH physical channel according to a first mode, hereinafter referred to as the discontinuous transmission mode of the UL DPCCH physical channel or the discontinuous reception on at least one downlink physical channel according to a second mode, for example on the physical channel 16 F-DPCH and / or the control channels of the HSUPA such as the physical channels E-HICH, E-AGCH, E-RGCH, HS-SCCH, and HS-DPSCHs, ci after designated discontinuous reception mode of the downlink physical channels. F-DPCH is an acronym for Fractional Decided Physical Channel, HSUPA stands for High Speed Uplink Packet Access, E-HICH stands for Enhanced uplink - ARQ Indicator Channel Hybrid, E-AGCH stands for Enhanced uplink Absolute Grant Channel and E-RGCH stands for Enhanced uplink Relative Grant Channel. Depending on the CPC commands considered, after having configured a telecommunication terminal 10, it is possible to activate or deactivate the discontinuous transmission mode of the UL DPCCH physical channel or the discontinuous reception mode of the downlink physical channels by signaling independently. adapted transmitted to the telecommunications terminal 10 via the physical channel HS-SCCH. According to another example, the other information is HS-SCCH commands representative of a request for reception of information transmitted for a telecommunication terminal 10 on a physical broadcast channel, so that the telecommunication terminal 10 is informed if he has to listen / decode the physical downlink channel permanently. In another example, the other information is HS-SCCH commands representative of a packet acknowledgment transmitted on the uplink. In another example, the other information is data flow control commands transmitted on the uplink. According to another example, the other information items are antenna weighting weight signaling messages used for transmission on the downlink according to a transmission diversity technique, or a multiple input multiple output technique, better known by the acronym acronym. -Saxon MIMO, acronym for Multiple-Input Multiple-Output. It should be noted here that the aforementioned examples can be taken in combination.

  In the next step E406, the processor 200 obtains a value associated with the other information. For example, the processor 200 selects one of the values included in the area 700 of FIG. 7c. According to another example, the processor 200 selects the first four bits of one of the values included in the area 700 of FIG. 7c, in this case the binary value 1110, as the value of a subfield 600 shown in FIG. 6b. The binary value 1110 is a first signaling sub-information of the transmission of a command intended for the telecommunication terminal. Fig. 6b represents an example of a control message comprising non-representative information of a resource allocation according to the present invention. Field 620 of FIG. 6a is at least equivalent to the subfields 600, 601, and 603 of FIG. 6b. The subfield 601 includes a sub information identifying the type of command intended for the telecommunication terminal. For example, when the command is a CPC command, the processor 200 selects the value 00 for the fifth and sixth bits corresponding to the sub-field 601. The processor 200 sets the value of the seventh bit included in the subfield 603 according to FIG. whether to activate the "discontinuous reception of F-DPCH and HSPA DL channels" mode or the discontinuous reception of F-DPCH and downlink HSPA physical channels as presented in technical report 3GPP TR 25.903 v1.2.0 on "Continuous Connectivity for Packet Data Users ". At this same step, the processor 200 sets the value of the equivalent bit to the first bit of the field 630 of FIG. 6a according to the activation or not of the "discontinuous reception of F-DPCH and HSPA DL channels" mode or discontinuous reception of the F-DPCH and the downlink HSPA physical channels as presented in the technical report 3GPP TR 25.903 v1.2.0 on "Continuous Connectivity for Packet Data Users". This bit is included in the subfield noted 604 of FIG. 6b. Alternatively, when the command is a CPC command, the processor 200 selects the value 000 for the fifth, sixth and seventh bits, sets the value of the equivalent bit to the first bit of the field 603 of FIG. 6a according to the activation or not of the "discontinuous reception of F-DPCH and HSPA DL channels" mode. This bit is included in the subfield noted 603 of FIG. 6b and sets the value of the equivalent bit to the second bit of the field 603 of FIG. 6a according to the activation or not of the mode "discontinuous reception of F-DPCH and HSPA DL channels". This bit is included in the subfield noted 604 of FIG. 6b.

  In the next step E407, the processor 200 inserts the value of the word obtained in the previous step in the fields 600, 601, 603 and 604 of FIG. 6b. In the next step E408, the processor 200 controls the transfer of the control message via the transmission and / or reception means 205.

  When this is done, processor 200 returns to step E400. Fig. 5 represents an algorithm executed by a telecommunication terminal according to the present invention. More specifically, the present algorithm is executed by the processor 300 of each telecommunication terminal 10.

  It should be noted here that, in the context of an implementation of the present algorithm according to the 3GPP TS 25.212 ver 7.2.0 standard, the present algorithm is executed by the processor 300 for each HS-SCCH physical channel. In step E500, the processor 300 detects the reception of a message by the transmitting and / or receiving means 305.

  The received message is more precisely a control message transmitted by the base station 20 in step E404 or in step E408 of the algorithm of FIG. 4. In the next step E501, the processor 300 reads the value of the word obtained in the previous step in at least one field of the received control message. In the next step E502, the processor 300 verifies whether the value of the word is representative of the allocation to the telecommunication terminal 10 of a given subset of resources of the telecommunication interface 50. The verification is for example carried out With the aid of a table stored in the nonvolatile memory 302. In the above example, the processor 300 verifies that the four most significant bits of the word included in the field do not correspond to the binary sequence 1110. the four most significant bits of the word do not correspond to the bit sequence 1110, the processor 300 proceeds to the step E505. If the four most significant bits of the word correspond to the bit sequence 1110, the processor 300 proceeds to step E503. In step E503, the processor 300 determines, from the subfields 601, 603 and 604, the non-representative information of the allocation to the telecommunication terminal 10 of a subset of other resources. The subfield 601 is representative of the type of command or order transmitted.

  For example, when the command is a CPC command, the subfield 601 is at the value 00, or alternatively 000, the subfield 603 is representative of the activation or not of the "discontinuous reception of F-DPCH" mode. HSPA DL channels "and sub-field 604 is representative of whether or not the mode of" discontinuous reception of F-DPCH and HSPA DL channels is enabled. "Other values of fields 601, 603 and 604 such as those mentioned above are for example representative of HS-SCCH commands relating to a request for reception of information transmitted for a telecommunication terminal 10 on a physical broadcast channel, so that the telecommunication terminal 10 is informed whether it has to listen / decode this physical channel permanently or are representative of HS-SCCH commands relating to an acknowledgment of packet transmitted on the uplink or representative of data flow control commands transmitted on the link uplink ante or are representative of the antenna weighting weight signaling messages used for downlink transmission according to a transmission diversity technique. In the next step E504, the processor 300 configures the transmitting and / or receiving means 305 so that they execute the command determined in step E503.

  When this is done, processor 300 returns to step E500. In step E505, the processor 300 determines the other resources of the telecommunication interface 50 that are allocated to the telecommunication terminal 10. The resources are determined from a correspondence table for the pair (O, P) or using the following algorithm.

  In the next step E506, the processor 300 configures the transmitting and / or receiving means 305 so that they use the determined resources. When this is done, processor 300 returns to step E500. Of course, the present invention is not limited to the embodiments described herein, but encompasses, on the contrary, any variant within the scope of those skilled in the art and particularly the combination of different embodiments of the present invention.

Claims (19)

  1) Method for transferring information from a base station to a telecommunication terminal on at least one resource of a telecommunication interface according to which the base station and the telecommunication terminal are connected, the information being transmitted in a field of a control message, the field comprising a word, characterized in that the method comprises the steps performed by the base station: -obtaining, when allocating a given subset d other resources of the telecommunication interface to the telecommunication terminal, a value of the word among a set of values, the number of values in the set of values being less than the number of values that the word is likely to take , each value of the set being representative of the allocation to a telecommunication terminal of a given subset of other resources of the telecommunication interface, - obtaining of a value of the word different from each value of the set of values if information not representative of an allocation of a given set of other resources is transferred, - insertion of the value of the word obtained in the message field control, - transfer of the control message.   2) Method according to claim 1, characterized in that the field is included in a header of the control message.   3) Method according to claim 1 or 2, characterized in that the other resources of the telecommunication interface are numbered and if at least two other resources are allocated to a telecommunication terminal, the resources have consecutive numbers and in that each value representative of the allocation to a telecommunication terminal of a given subset of other resources of the telecommunication interface is obtained from the number of another resource allocated to the telecommunication terminal and the number of other resources allocated to the telecommunication terminal.   4) Method according to claim 3, characterized in that the field value is broken down into a first and a second sub-value, the first sub-value being obtained from the number of other resources allocated to the telecommunication terminal and the second sub-value being obtained from the number of other resources allocated to the telecommunication terminal and the number of the other resource having the lowest number among the numbers of the other resources allocated to the telecommunication terminal.   5) Method according to claim 4, characterized in that the word consists of a first and a second sub-word, the first sub-word having three bits, the second sub-word comprising four bits, the first sub-word comprising -value being calculated according to the following formula: x, cs, xccs, 2, xecs, 3 = min (P -1.15-P) where x ccs, l, xccs, i, xce5.3 are respectively the first, second and third bits of the first subword, min (x, y) represents the minimum value of the elements of the pair x, y, P is the number of other resources allocated to the telecommunication terminal and 15 is the total number of others telecommunication interface resources and the second sub-value being calculated according to the following formula: xe ,, s, xc ,, 6, xe ,, 7 = 10 û 1 û LP / 8 j * 151 where are respectively the first second, third, and fourth bits of the second subword, 1x1 represents the absolute value of x, Lx] represents the integer part of x and O is the number of the other resource having the lowest number among the numbers of the other resources allocated to the telecommunication terminal.   6) Method according to any one of claims 1 to 5, characterized in that the telecommunication interface is a telecommunication interface using a code division multiple access method and in that the non-representative information of an allocation of a given subset of other resources includes a first signaling sub-information of the transmission of a command for the telecommunication terminal.   7) Method according to claim 6, characterized in that the first signaling sub-information of the transmission of a command for the telecommunication terminal is represented by the following bit 1110.   8) Method according to claim 6 or 7, characterized in that the non-representative information of an allocation of a given subset of other resources comprises a second sub-information identifying the type of command for the telecommunication terminal .   9) Method according to claim 8, characterized in that the command is a command authorizing the discontinuous transmission of the telecommunications terminal to the base station on at least one other resource of the telecommunication interface or the discontinuous reception of the station base to the telecommunication terminal on at least one other resource of the telecommunication interface.   10) A method of receiving information transmitted by a base station to a telecommunication terminal on a resource of a telecommunication interface according to which the base station and the telecommunication terminal are connected, the information being transmitted in a field of a control message, the field comprising a word, characterized in that the method comprises the steps performed by the telecommunication terminal of: - receiving at least the control message field, - determining whether the value of the word understood in the field is representative of the allocation to the telecommunication terminal of a given subset of other resources of the telecommunication interface or if the value of the word included in the field is not representative of an allocation of a given set of other resources.   11) Method according to claim 10, characterized in that the field is included in a header of the control message.   12) A method according to claim 10 or 11, characterized in that the non-representative information of an allocation of a given subset of other resources comprises a first sub-information signaling the transmission of a command for at the telecommunication terminal. 23   13) Method according to claim 12, characterized in that the first signaling sub-information of the transmission of a command for the telecommunication terminal is represented by the following bit 1110.   14) Method according to claim 12 or 13, characterized in that the non-representative information of an allocation of a given subset of other resources comprises a second sub-information identifying the type of command for the telecommunication terminal .   15) Method according to claim 14, characterized in that the command is a command authorizing the discontinuous transmission of the telecommunication terminal to the base station on at least one other resource of the telecommunication interface or the discontinuous reception of the station base to the telecommunication terminal on at least one other resource of the telecommunication interface.   16) Base station able to transfer information to a telecommunication terminal on at least one resource of a telecommunication interface according to which the base station and the telecommunication terminal are connected, the information being transmitted in a field of communication. a control message, the field comprising a word, characterized in that the base station comprises: means for obtaining, when allocating a given subset of other resources of the telecommunication interface at the telecommunication terminal, a value of the word among a set of values, the number of values included in the set of values being less than the number of values that the word is likely to take, each value of the set being representative the allocation to a telecommunication terminal of a given subset of other resources of the telecommunication interface, - means for obtaining a value of the different word e of each value of the set of values if information not representative of an allocation of a given set of other resources is transferred, - means for inserting the value of the word obtained in the control message field means for transferring the control message. 24   17) Telecommunication terminal able to receive, from a base station, information transmitted on a resource of a telecommunication interface according to which the base station and the telecommunication terminal are connected, the information being transmitted in a field a control message, the field comprising a word, characterized in that the telecommunication terminal comprises: - means for receiving at least the control message field, - means for determining whether the value of the word included in the field is representative of the allocation to the telecommunication terminal of a given subset of other resources of the telecommunication interface or if the value of the word included in the field is not representative of an allocation of one together given other resources.   18) computer program stored on an information carrier, said program comprising instructions for carrying out the method according to any one of claims 1 to 9 when executed by an electronic device.   19) computer program stored on an information carrier, said program comprising instructions for carrying out the method according to any one of claims 10 to 14 when it is executed by an electronic device.