JP4808894B2 - Signaling transmission method - Google Patents

Description

[0001]
The present invention relates to a signaling transmission method according to the superordinate concept of the independent claims.
[0002]
A signaling transmission method between a mobile station and a base station in a mobile radio network is already known, for example, from the publication “Fast Uplink Signaling Mechanism for FDD and TDD System”, Tdoc SMG2 UMTS-L1 227/98, Philips Research Laboratories, 1998 It is.
[0003]
On the other hand, the method of the present invention having the structure of the independent claim has the following advantages. That is, signaling is transmitted in at least one predetermined time slot, and one different signaling is assigned to each mobile station assigned to the radio cell of the base station, so one time lag is assigned to each of these mobile stations. , shifted amount this time by shifting the predetermined signaling sequence is transmitted in at least one predetermined time slot, Ru is transmitted through the at least one predetermined time slot, at the base station the signaling of various mobile stations Since it can be distinguished and only one time slot and one predetermined signaling sequence are required, clear and efficient signaling can be realized. Therefore, it is usually not necessary to repeat this signaling transmission. This signaling therefore gives the desired result very quickly. In this case, the use of transmission resources is minimized. At this time, signaling of a plurality of mobile stations is possible by using only one common time slot.
[0004]
The arrangements implemented in the dependent claims make possible other advantageous configurations and improvements of the method described in the independent claims.
[0005]
Advantageously, each signaling is assigned to these mobile stations in the form of a different code. This is especially true for mobile radio systems based on code division multiple access with orthogonal codes, which can implement simple and efficient signaling using available codes without requiring much additional transmission resources. Is shown.
[0006]
Also advantageously, the mobile station assigned to the received signaling is detected by correlating the signaling received at the base station with all codes assigned to the mobile station. In this way, the base station can clearly determine the mobile station that transmits the signaling.
[0008]
Also advantageously, this predetermined signaling sequence is spread and transmitted by one predetermined code. In this way, signaling transmission can be realized with a minimum transmission capacity. This is particularly possible when this predetermined code is extracted from a set of orthogonal codes, for example for use in a code division multiple access system.
[0009]
Also, advantageously, the base station detects the time lag used from the time-dependent amplitude characteristics of the received predetermined signaling sequence, thereby detecting the assigned mobile station. In this way, the base station can clearly determine the mobile station that transmits the signaling.
[0010]
Also advantageously, this signaling is transmitted with much less power than that required to transmit usage data. In this way, additional interference due to signaling can be minimized.
[0011]
Also advantageously, at least one of the signaling is transmitted in at least one predetermined time slot together with other signaling or usage data of an existing connection. Thereby, transmission capacity can be reduced.
[0012]
Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 shows a simplified mobile radio system, FIG. 2 shows a burst structure for transmission in the time slot duplex mode, FIG. 3 shows a transmission frame structure in the time slot duplex mode, and FIG. 4 shows a code tree for code generation. Show.
[0013]
For example, in the mobile radio system 10 that can be configured according to the GSM standard (Global System for Mobile Communication) or the UMTS standard (Universal Mobile Telecommunications System), the downlink transmission direction 13 from the fixed base station 11 to a mobile station 12 in FIG. In the uplink transmission direction 14 from the mobile station 12 to the base station 11, for example, in addition to so-called utilization data that exists in the form of a speech signal, for example, signaling data for handover procedures or new channel configuration must also be transmitted . In the following, the invention is described on the basis of a mobile radio network based on the mobile radio system 10 according to the UMTS standard, for example. Hereinafter, this is referred to as a UMTS mobile radio system 10.
[0014]
The UMTS mobile radio system 10 is provided with two modes for transmission via an air interface. In the FDD mode (Frequency Division Duplex), there are two different frequencies for the upstream transmission direction 14 and the downstream transmission direction 13. In the TDD mode (Time Division Duplex), only one carrier frequency is used for both transmission directions, and at this time, the downlink transmission direction 13 and the uplink transmission direction 14 are separated by time slot assignment.
[0015]
The signals of various subscribers of this mobile radio network are separated from each other by spreading of orthogonal codes. In the TDD mode, the signals of various subscribers spread in this way are transmitted in the same time slot.
[0016]
Hereinafter, for example, it is assumed that the UMTS mobile radio system 10 shown in a simplified manner in FIG. 1 is configured according to the TDD mode. FIG. 3 shows the structure of the transmission frame 30 used for this purpose. Each transmission frame has a time length of 10 ms in this example, and is composed of a total of 15 time slots 301, 302,. Here, it is assumed that the first time slot 301 is reserved for transmission in the upstream transmission direction 14 and the second time slot 303 is reserved for transmission in the downstream transmission direction 13. Within each time slot 301, 302,... 315, the so-called TDD burst 20 of FIG. The TDD burst 20 includes two data blocks 21 and 23 for data transmission, a midamble block 22 for channel evaluation, and a protection distance 24.
[0017]
Within each time slot 301, 302,... 315, the usage data of a maximum of 16 subscribers can be transmitted according to the code division multiple access (CDMA) principle. In order to achieve this, the usage data to be transmitted by each subscriber must be spread in the corresponding time slots before being superimposed. FIG. 4 shows a code tree, which is used to generate a so-called OVSF code (Orthogonal Variable Spreading Factor) for spreading the usage data to be transmitted.
[0018]
In addition to these usage data, signaling is also transmitted between the mobile station 12 and the base station 11. These signaling can be used, for example, to request a transmission channel, send a command for controlling the transmission power, or transmit a reference signal for channel evaluation. In any of the above cases, a station that receives the signaling will respond to this signaling. In these illustrated cases, this response is a channel impulse response based on a received reference signal for use in transmission channel assignment, transmission output setting, or predistortion by, for example, JP (Joint Predistortion). It is evaluation of. The following describes how such signaling is transmitted from the mobile station 12 to the base station 11 based on, for example, signaling for transmission channel request.
[0019]
According to the first embodiment, these signaling are generated from the OVSF code described above. The code tree shown in FIG. 4 shows the generation of OVSF codes up to spreading factor SF = 8. In the TDD mode of the UMTS mobile radio system 10, an OVSF code having a spreading factor SFε {1, 2, 4, 8, 16} is possible at this point. An orthogonal code sequence can be generated using this OVSF code, but the basic characteristic is that codes of different lengths also have orthogonality.
[0020]
In the first embodiment of the present invention, it is assumed that signaling can be transmitted only in the first time slot 301. In this first time slot 301, all signaling is generated from a predetermined length 16 spreading code and spreading factor SF = 16. For example, the last spreading code with spreading factor SF = 16 is selected, where the code tree described up to the bottom spreading factor SF = 8 in FIG. 4 continues correspondingly. The lowermost branch of the code tree having spreading factor SF = 16 is expanded to spreading factor or length 256. Thus, a total of 16 codes can be used for signaling in the first time slot 301. In other words, 16 codes with OVSF code spreading factor 256 are used for signaling.
[0021]
These signaling length 256 codes are used to construct a signaling burst. This has the same structure as the TDD burst 20 described in FIG. At this time, the signaling code is repeated in the data blocks 21 and 23 as long as these data blocks are filled. The signaling code can then be disconnected at the last iteration required to fill the data blocks 21,23. In this first time slot 301, the midamble block 22 is similarly assigned to any TDD burst 20 thus configured as a signaling burst.
[0022]
In this mobile station 12, for example, when the base station 11 enters the radio cell, among the above-described signaling codes, there is one that is arranged completely below when the spreading factor SF = 256 in the code tree of FIG. Assigned. In addition, it can be arranged that this mobile station 12 has the signaling authority in the first place. Then, no signaling code is assigned to a mobile station that does not have this signaling right. A different signaling code is assigned to any mobile station having a signaling right. When this mobile station 12 needs a channel for data transmission in the upstream transmission direction 14, which will be referred to as an upstream channel hereinafter, this mobile station 12 requests such a channel in the first time slot 301, The signaling code assigned to the mobile station 12 is transmitted. Thereafter, the base station 11 notifies the mobile station 12 of such parameters for the uplink channel in the second time slot 303. Since this assigned uplink channel is also in the first time slot 301 at this time, the mobile station 12 similarly starts use data transmission in the first time slot 301 in the subsequent transmission frame 30. be able to.
[0023]
The transmission power of the signaling burst 20 is much lower than the transmission power of a normal burst for use data transmission. This minimizes additional interference in the upstream transmission direction 14 due to the use of the signaling burst 20. Detection of the signaling code received at the base station 11 and the mobile station 12 assigned to this signaling is performed by correlating with 16 different predetermined signaling codes. These signaling codes can also be detected by the JD method (Joint Detection).
[0024]
If these predetermined 16 signaling codes are too few in the first time slot 301, which is the only time slot used for signaling per transmission frame 30, the signaling transmission is routed to an additional time in the upstream transmission direction 14. Can be extended to slots. Similarly, it is conceivable to increase the number of predetermined signaling codes by using a spreading factor greater than 256 in these code generation code trees. For example, when extending to spreading factor SF = 1024, a total of 64 signaling codes can be used.
[0025]
In the second embodiment, this signaling can be realized in another way. In the first embodiment, the OVSF code is used as a direct signaling code. In the second embodiment, a certain OVSF code having a spreading factor SF = 16, for example, the lowest code in the code tree having a spreading factor SF = 16 is certainly reserved for signaling. However, this code is used to spread a predetermined signaling sequence for any signaling and for any mobile station having signaling rights in the base station 11 radio cell. This signaling sequence is the same and specific symbol sequence for a mobile station having all signaling rights in the radio cell of the base station 11, which has good autocorrelation characteristics. This signaling sequence is spread using the OVSF code previously given or reserved for it and transmitted in the data blocks 21, 23 of the signaling burst 20. Since this signaling sequence is composed of many symbols, it is spread with a spreading factor SF = 16 and continues as long as the data blocks 21 and 23 are combined. Every mobile station that uses this signaling sequence is assigned a different time lag to start the signaling sequence. The mobile station 12 starts this signaling sequence simultaneously with the start of the signaling burst 20 used for signaling shown in FIG. A mobile station (not shown) in the radio cell of the base station 11 starts the signaling sequence with a delay of, for example, 4 symbols. This corresponds to a time shift of 64 chips. However, since this signaling sequence has 4 symbols more than can be transmitted in the data blocks 21 and 23 from the above time lag, these 4 remaining symbols are transmitted at the beginning of the signaling burst 20. . Therefore, this signaling sequence is transmitted to various mobile stations with periodic shifts, where each time shift clearly identifies the mobile station 12 assigned to this time shift. The time offset for each of these mobile stations consists of a multiple of 4 symbols after spreading or a multiple of 64 chips with spreading factor SF = 16. This value of 4 symbols corresponds to the maximum length that occurs in a 64 chip transmission channel. This results in 30 possible different time shifts or 30 different mobile stations per time slot used for signaling in the uplink transmission direction 14 at this point. This periodically shifted signaling sequence is then further spread with the above-described predetermined OVSF code so as to ensure orthogonality to other signals transmitted in the same time slot. Again, each signaling burst 20 is assigned a unique midamble block 22.
[0026]
Similarly, the transmission output of the signaling burst 20 is very small compared to the utilization data burst. The detection of the signaling burst 20 received by the base station 11 is performed after being despread by a matched filter having peak detection, for example. Depending on which time position in the amplitude curve of the received and despread signaling burst 20 the maximum value occurs, the underlying time lag and the mobile station assigned to it can be estimated, and this signaling can You can start according to the structure of the up channel done. This signaling burst despreading can also be performed by the JD method.
[0027]
In two embodiments, signaling can be detected very quickly if the transmission quality allows: That is, if this detection quality is already sufficient to make a reliable decision in the first data block 21, the evaluation of the second data block 23 can be abandoned.
[0028]
In yet another embodiment, the spread signaling sequence can additionally be configured to be transmitted only in one of both data blocks 21, 23. Moreover, this signaling sequence is half as long as the above embodiment. As a result, various mobile stations can additionally identify which of the data blocks 21 and 23 the signaling sequence is transmitted to and received by the base station 11 at the base station 11.
[0029]
Due to the fixed division of these time slots in different transmission directions, i.e. the downlink transmission direction 13 or the uplink transmission direction 14, the advantage of rapid signaling in the uplink transmission direction 14, for example, may be limited by the situation. This can occur particularly when only one time slot is allocated per transmission frame 30 in the upstream transmission direction 14.
[0030]
This can occur because the transmission of signaling in the upstream transmission direction 14 in the first or second embodiment is also possible using the time slot in the downstream transmission direction 13. In general, this signaling can be transmitted in one common time slot along with other signaling or existing connection usage data.
[0031]
Since very little transmission power is provided for the signaling burst 20 transmission, only slight additional interference is expected. However, at this time, in both the first and second embodiments, it must be ensured that the spreading code having the spreading factor SF = 16 reserved for signaling transmission is not used in the downlink transmission direction 13.
[0032]
The use of one common time slot for signaling according to the method described above forms a unique signaling channel, also called FAUSCH (Fast Uplink Signaling Channel), for the upstream transmission direction 14. Even if a new channel is inserted in the uplink transmission direction 14 by this FAUSCH, there is only a necessary change in the mobile station 12 and the base station 11.
[0033]
The method according to the invention advantageously allows the mobile station 12 to transmit, for example, 1-bit signaling in the TDD mode to the base station 11 without a time delay in a predetermined or predetermined common first time slot 301. Have This signaling then gives a predetermined response at the base station 11 and at the same time does not indicate any significant degradation of the other channels.
[Brief description of the drawings]
FIG. 1 is a simplified diagram showing a mobile radio system.
FIG. 2 is a diagram showing a burst structure for transmission in a time slot duplex mode.
FIG. 3 is a diagram showing a transmission frame structure in a time slot duplex mode.
FIG. 4 is a diagram illustrating a code tree for code generation.

Claims (11)

Transmitting signaling in at least one predetermined time slot (301) and assigning one different said signaling to each mobile station (12) assigned to the radio cell of the base station (11) ,
In a signaling transmission method between a mobile station (12) and a base station (11) in a mobile radio network,
One time lag is assigned to each of the mobile stations, and one predetermined signaling sequence is shifted by at least one predetermined time slot (301) and transmitted by the time lag,
Characterized by distinguishing the relevant transmitted via at least one predetermined time slot, the signaling various mobile stations at the base station (11), a signaling transmission method. The predetermined signaling sequence, and transmits the spread by one predetermined code, the signaling transmission method of claim 1, wherein. At the base station, from the time amplitude curve of the received predetermined signaling sequence, detects the time shift that was used to detect the mobile stations assigned the signaling transmission of claim 1 or 2, wherein Method. At least one predetermined time slot (301) in the assigned burst (20) of only one data block of the two data blocks (21, 23), and transmits the spread signaling sequence, claim 4. The signaling transmission method according to 2 or 3 . The signaling transmission method according to claim 4 , wherein the base station (11) detects one of two data blocks (21, 23) to which a signaling sequence is transmitted and detects the assigned mobile station. . The signaling transmission method according to any one of claims 1 to 5 , wherein the signaling is transmitted with an output much smaller than an output for use data transmission. The signaling transmission method according to any one of claims 1 to 6, wherein at least one of the signaling is transmitted in at least one predetermined time slot (301) together with other signaling or existing connection usage data. . The signaling transmission method according to any one of claims 1 to 7, wherein the mobile radio network is operated using an orthogonal code according to a CDMA-TDD system (CDMA = Code Division Multiple Access; TDD = Time Division Duplex). . The signaling transmission method according to any one of claims 1 to 8 , wherein a request for a transmission channel for establishing a connection between the mobile station (12) and the base station (11) is transmitted using the signaling. The signaling transmission method according to claim 1, wherein a command for controlling a transmission output is transmitted using the signaling. The signaling transmission method according to any one of claims 1 to 10 , wherein a reference signal for channel evaluation is transmitted using the signaling.

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