JPH05259981A - Zone selecting method for switching of busy channel - Google Patents

Abstract

PURPOSE:To improve the availability of frequency by providing such a constitution where each base station transmits its own zone information in a cycle where two cycles are alternately repeated and a mobile station receives the zone information from each base station with no collision of these information. CONSTITUTION:Each base station transmits its own zone information alternately in two cycles, i.e., T1=T+alpha and T2=T-alpha which are slightly offset before and after a fixed reference cycle T. For instance, the base station of zone 1 transmits its own zone information in a certain frame and through a 1st time slot and then in the next frame and through a 3rd time slot respectively. Therefore a mobile station can prevent the collision of those zone information sent from each base station and can receive the accurate its own zone information. Thus each base station can use the common control frequency and the availability of frequency is improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a zone selection method capable of effective frequency use suitable for channel switching during a call in a mobile communication system using the TDMA-TDD system.

[0002]

2. Description of the Related Art FIG. 2 shows a control frequency allocation in a conventional system. The mobile station 1 is currently focused on. Here, there are six zones (zone 2 to zone 2) around the zone in which the mobile station 1 is located, that is, the zone of interest (zone 1).
The case where there is zone 7) is shown. One different control-specific frequency f1 to f7 is assigned to each zone. The communication frequency is common to all zones, and the frequency that is available at the start of a call is used.

FIG. 3 is a diagram showing a state of a control-dedicated frequency transmitted from each zone and a method of using a time slot during a call in a mobile station. (A) to (D) are states of the control-dedicated frequency transmitted from each zone 1 to 7, and (A) is the zone 1
From the continuous transmission at frequency f1 from
Shows continuous transmission from zone 7 at frequency f7. Further, (e) is a diagram showing how to use a time slot during a call in a mobile station, and shows an example in which one frame is composed of four time slots. Reference numeral 10 is a frame used by the mobile station 1 for transmission, and 11 is a frame used by the mobile station 1 for reception. Since it is premised on the TDMA-TDD system, transmission and reception are sequentially repeated for each frame. Reference numerals 101 and 111 denote time slots allocated for communication, 101 for mobile station transmission and 111 for mobile station reception. Here, the first time slot is shown for a call, but of course, this time slot is appropriately determined for each call. 102 and 112 are mobile stations 1
Is a time slot that is not used for a call, and is a time slot that is used by another mobile station for a call or is empty. Also, here, the time slots 111 and 11
Although the heights of 2 and 102 are displayed differently, this is because the height is intended to represent the reception level of the mobile station. That is, in this figure, the highest level of reception is possible from zone 1, then zone 5 and then zone 6.

The mobile station 1 constantly monitors the control-dedicated frequency of the peripheral zone at time slots (called unused time slots here) 102 and 112 which are not used during the call, and measures and stores the reception level thereof. To do. That is, the mobile station 1 transmits a call signal to the base station of the zone 1 in the time slot 101, receives the control-dedicated frequency f6 of the zone 6 in the unused time slot 102, and stores the reception level. Of course, if the reception level is below a certain level, it may be discarded without being stored. In addition, after receiving a call signal from the base station in zone 1 in time slot 111, in zone 5 in unused time slot 112
The control-dedicated frequency f5 is monitored. Further, in the unused time slot of the next frame, the control dedicated frequency of zone 4 or zone 3 is monitored in the same manner as above. In this way, the mobile station 1 constantly monitors the control-dedicated frequency from the peripheral zone during a call and stores the reception status, and the reception level of the zone (zone 1) during the call becomes small and channel switching is performed. When the necessity arises, the transfer destination zone is determined based on the stored information and the channel is switched. The operation procedure of this mobile station is shown in FIG.

[0005]

In the above-mentioned prior art, it is necessary to make the control exclusive frequency of each zone different,
There was a drawback that the frequency utilization efficiency was poor. That is,
A number of control frequencies corresponding to the number of zones in which the frequencies are repeatedly used are required. An object of the present invention is to realize a zone selection method with excellent frequency utilization efficiency in switching channels during a call.

[0006]

In order to achieve the above object, the zone selection method of the present invention uses a control channel common to each zone and a plurality of communication frequencies in a mobile communication system using the TDMA-TDD system. Allocation, the base station of each zone uses a slot different from the control signal transmission slot of another base station and uses the control channel to generate two periods T ₁
And T ₂ are alternately repeated, the mobile station transmits its own zone information, and the mobile station monitors the control channel in a time slot that is not used for the call during the call, and determines the transfer destination zone based on the reception status. To do.

[0007]

In the present invention, each base station transmits its own zone information in a cycle in which two cycles are alternately repeated,
Since the mobile station can prevent the collision of its own zone information from each base station and receive the own zone information accurately,
A common control frequency can be used for each base station, and frequency utilization efficiency can be improved.

[0008]

FIG. 5 shows an example of control channel frequency allocation in each zone according to the present invention. One common control frequency f1 is assigned to each zone. The communication frequency is the same as the conventional one. FIG. 1 is a diagram showing a state of transmitting own zone information (also simply referred to as zone information) on the control channel f1 in each zone and a method of using a time slot during a call in a mobile station. (A) shows how zone information is transmitted in zone 1, where zone information is transmitted in the hatched slots. (B) is a similar view in zone 2, and is slot information in which slot 107 indicated by diagonal lines is transmitted. (C) is a similar view in Zone 3, 108 and 1
09 is zone information. Let T be the time from the time slot of a certain frame to the time slot of the same number of the frame in which the zone information is transmitted next. Here, an example is shown in which one frame is composed of four time slots. (4-channel TDMA). As will be described later in (d), the length of one frame in the communication channel is S and T = NS (N is an integer). For example, the zone number) is transmitted. Here, an example is shown in which the zone information is transmitted once for N frames.

The greatest feature of the present invention lies in the method of transmitting the zone information, which will be described in detail below. As will be described later, each base station detects a collision with a control channel signal of another base station at the time of starting operation, performs burst 1 slot transmission at a time when the collision does not occur, and thereafter transmits periodically. Therefore,
Control signals from multiple base stations can be transmitted without colliding with each other. However, when the mobile station happens to collide with a time slot during a call of the mobile station by transmitting at a constant period T, the mobile station cannot receive the zone information from the base station. (In this figure, the signal 108 transmitted from the base station in zone 3 is not received.) Further, since the frame period T and the transmission or reception frame length S of the mobile station are in an integral multiple relationship, the base station once collided Since the zone information from the stations continues to collide, it cannot be received any longer. Therefore, in the present invention, it is the maximum to alternately transmit the zone information in two cycles of T ₁ = T + α and T ₂ = T−α which are offset slightly forward and backward with respect to T as a reference for each base station. It is a feature of. Specifically, for example, a base station in zone 1 may transmit its own zone information using a first time slot in a certain frame, and then transmit it using a third time slot in the next frame. Of course, the second and fourth slots may be used alternately. Also, here, the case of 4-slot multiplexing is taken as an example, but if the number of time division multiplexes is further increased, various transmission patterns may be possible. However, since the base stations in each zone are not frame-synchronized with each other, some time lag occurs.

(E) is a diagram showing how to use a time slot during a call in a mobile station, 10 is a transmission frame of the mobile station, and 11 is a transmission frame of the mobile station.
Is the received frame. The frame length of the communication channel is S
Is. Time slots 101 and 102 are allocated for a call, and these are the same as in the conventional case. Note that the method of using the time slot during standby before entering a call is different from this, but is not described here because it is irrelevant to the present invention.
Unused time slots 103, 104, 105, and 106 are so-called monitor times during which the reception frequency is set to f1 to receive zone information from the peripheral zone. This time slot is set synchronously with the base station of zone 1 with which the mobile station is currently communicating.

In this example, the zone information 107 from the zone 2 can be received at the monitor time 104, but at the monitor time 103, the zone information 108 transmitted from the zone 3 at the third time slot is received by the mobile station. This is a case in which the time slot R1 collides with the time slot and the signal cannot be received. However, since the base station in zone 3 transmits zone information 109 at a time point offset from the cycle T, such as transmitting in the first time slot in the frame in which zone information is transmitted next, this signal is transmitted by the mobile station. It becomes possible to avoid the collision with the transmission or reception time slot by entering the monitor time 105 of the above, and the mobile station can receive.

In this figure, the height of the zone information that can be received by the mobile station during the monitor time is shown differently, but this height is the same as in the conventional case. In this example, the reception level from the zone 3 is high and the reception level from the zone 2 is very low. In this case, it can be seen that the mobile station is moving from zone 1 to zone 3.

FIG. 6 shows an operation procedure during a call of the mobile station according to the present invention. Step S1 is a step during a call, for example, a call is made at the communication frequency ft and the first time slot (see FIG. 1). S2 is a zone information monitoring step of the peripheral zone in the unused time slot, which is an operation during the monitor time (see FIG. 1) using the frequency f1. S3 is a step of temporarily storing the contents of the zone information that can be received and the reception level value in the buffer. S4 is the reception level value on the memory for the same peripheral zone and the step S
This is a step of rewriting the reception level value in the memory by taking the average with the reception level value in the buffer measured in 3. Since the mobile station reception level fluctuates greatly instantaneously due to multipath fading while moving, the fluctuation is smoothed by taking a moving average. S5 is a step of sorting the data on the memory in the order of reception levels. As a result, the zone having the maximum reception level among the peripheral zones is clarified, and the zone can be quickly selected when switching channels. Of course, this step does not have to be performed all the time,
It may be performed after entering the channel switching operation shown in S7. Further, the sorting method may be performed not only in the level order but also in the zone order. The steps S1 to S5 are constantly repeated during a call. Step S6 is a step of detecting that the reception level from zone 1 has decreased because the mobile station has moved from zone 1 to the peripheral zone. As a result, the operation switches to the channel switching operation during a call. This step is S7.
The above is the operation contents of the mobile station in the present invention.

FIG. 7 shows an example of the structure of a memory for storing the reception level. This is an example where the levels of 10 peripheral zones can be stored. 20 is a reception level value, which is, for example, a moving average value. In this example, the numbers are sorted in descending order of reception level starting from number 1. The level average is not limited to the moving average. Reference numeral 21 is zone information, which corresponds to a zone name (may be a zone identification number), a name of an exchange station connected to a base station of the zone, or the like. If the memory is configured in this way, the zone stored in number 1 can be determined as the migration destination zone.

FIG. 8 shows the configuration of the mobile station 1 suitable for the present invention. 31 is a transmitting unit, 32 is a receiving unit, 30 is a transmission / reception common unit,
40 is an antenna, 34 is a local oscillator synthesizer, 3
3 is a local oscillator for f1 reception (for example, TCXO), and 35 is a changeover switch. Communication time slots 101 and 10
In 2, the synthesizer 33 is used and the monitor time 103
In ~ 106, TCXO33 (Of course synthesizer 33
The synthesizer other than the above may be used), and the changeover switch 35 is switched. Reference numeral 36 is a baseband processing unit for processing a call signal, but since it is not directly related to the present invention, detailed description thereof will be omitted. Reference numeral 37 denotes a reception level storage memory, one example of which is described with reference to FIG. Reference numeral 38 is a level detection unit that measures the received signal level, and 39 is a control unit that controls the operation of the entire mobile station.
Of course, the operation shown in FIG. 6 is also performed under the control of the control unit 39.

FIG. 9 shows the operation procedure of the base station in the present invention. Step S11 is a step of turning on the power of the base station to start the operation, and S12 is a step of resetting the base station controller. S13 is a step of selecting a certain time slot. Specifically, there are various selection methods, but one example is a method of generating a random number in the control unit and selecting a slot having a number equal to the random number value. S14 is
In this step, the reception level (that is, the amount of interference) of the control frequency f1 is measured in the selected slot, and it is detected whether another base station has already used the slot for zone information. If the reception level is higher than the predetermined value, that is, another base station is already using the slot, the process returns to step S13 and the same steps are repeated for the other slots. If there is a slot that is not used by another base station, that slot is used as a zone information transmission slot for this base station in S15, and one slot of zone information is transmitted at frequency f1. Step S16 is a step of transmitting the next zone information after (T + α) has elapsed since the time of transmission in S15, and S17 is a time of (T-
In this step, the zone information is transmitted after α) has elapsed. After that, by repeating steps S16 and S17, the zone information is periodically transmitted while alternately repeating the cycles (T + α) and (T−α). Specifically, for example, in the case of 4-channel time division multiplexing, the transmission may be performed in the first slot in step S16 and then in the third slot in step S17. (Of course, other slots are used for communication with mobile stations.) FIG. 10 shows an example of the configuration of base stations arranged in each zone. This is an example of a base station when one zone is composed of one base station, but of course each zone may be composed of a plurality of base stations, and in that case the basic structure of the base station is the same. .. 50 is the entire base station, and 51 and 52 are antennas. This is done because the example of receiving diversity is used here.
Of course, a configuration without reception diversity is also possible. 501 and 502 are transmission / reception switching units, 503 is an antenna switching unit, 504 is a communication transmitting unit, and 505 and 506 are communication receiving units. Two receivers are needed to perform diversity. A local oscillator synthesizer 507 is connected to the transmitting unit 504 and the receiving units 505 and 506. An antenna switching control unit 508 compares the reception levels of the two receiving units 505 and 506 and controls switching of the antenna / receiving unit with the larger one. Reference numeral 509 is a reception level detection unit, and reference numeral 510 is a baseband processing unit that performs transmission / reception processing of communication signals. From here, the communication line is connected to the switching center (ISMA). A control unit 511 controls the operation of the base station. The control of transmitting the zone information f1 shown in FIG. 9 is also performed by the control unit 511.

In the above embodiments, the transition zone is detected by using the signal reception level from the base station. However, the error rate of the control signal may be used without being limited to the reception level. An example of this case will be described below. 11
7A and 7B are a signal configuration of own zone information transmitted from each base station using the control channel f1 and a configuration example of a base station selection memory in the mobile station (modification of FIG. 7). In addition to the information part, a unique word (UW) for synchronization is included in the own zone information.
Since the CRC bit for error check is added, the transfer destination zone can be detected by using the error rate of this UW or CRC bit. For example, when the UW is used, the number of error bits is obtained by detecting the UW correlation in the mobile station and stored in the memory. 22 is the number of error bits in this case. At the time of zone transition, the zone with the smallest number of error bits may be determined as the transition destination zone. This is because the number of error bits in 1 UW is small when the reception level is high, and large when the reception level is low. That is, reception level and U
Since the number of error bits of W has a substantially corresponding relationship, the operation of the mobile station when UW is used is equivalent to that in which the reception level in the above example is replaced with the number of error bits.

Further, when the CRC bit is used, it cannot be as easy as UW because it knows only whether or not the signal is received. In this case, the moving average of the reception rate over the immediately preceding several frames may be obtained for each zone and stored in the memory of the mobile station, and the zone having the smallest value may be determined as the transition destination zone. In this case, the memory 22 of the mobile station is usually arranged in ascending order of the moving average value of the non-reception rate (or in increasing order of the moving average value of the reception rate). (Of course, it is not limited to this, and different information may be stored as long as it is equivalent.) The operation of the mobile station in this case is also the one in which the reception level in the previous example is replaced with the reception rate. Is equivalent to

In the above embodiment, as shown in FIG. 1, the base station uses two cycles, but as a whole, the zone information is periodically sent. In this way, the signals from each base station do not collide, so it works effectively even if there are many base stations, but if the system does not have many base stations, it will send the zone information randomly. The embodiment which does is also effective. Of course, in this case, the base station detects the presence or absence of a signal collision with another base station before transmitting the zone information, and transmits when there is no collision. In this case, the base station has a collision detection function (interference detection) and a timer function for the time T. When the zone information for one slot is transmitted in a certain frame, the timer is turned on and waits for the time T, and the collision occurs after the timer is turned off. If there is a collision, it is transmitted, and if there is a collision, wait until there is no collision and then transmit.

[0020]

According to the present invention, it is possible to switch channels with the same zone detection and identification accuracy as the conventional one without using much frequency, and effective use of frequency can be realized, and a remarkable effect is obtained especially in a system having a minimum zone configuration. There is.

[Brief description of drawings]

FIG. 1 is a diagram showing how zone information is transmitted from each zone according to the present invention and how a mobile station uses a time slot during a call.

FIG. 2 is a diagram showing a frequency allocation for control channels in a conventional technique.

FIG. 3 is a diagram showing a state of zone information transmission from each zone and a usage method of a time slot during a call in a mobile station according to a conventional technique.

FIG. 4 is an operation of a mobile station during a call in the related art.

FIG. 5 is a diagram showing frequency allocation for control channels in the present invention.

FIG. 6 is an operation of the mobile station during a call according to the present invention.

FIG. 7 is a specific configuration example of a reception information storage memory provided in a mobile station.

FIG. 8 is a block diagram of a mobile station suitable for the present invention.

FIG. 9 is an operation procedure of a base station according to the present invention.

FIG. 10 is a block diagram of a base station suitable for the present invention.

FIG. 11 is another configuration example of the reception information storage memory provided in the mobile station.

[Explanation of symbols]

 10 Mobile Station Transmission Frame 11 Mobile Station Reception Frame 101 Mobile Station Transmission Signal 102 Mobile Station Reception Signal 103 Monitor Time 104 Monitor Time 105 Monitor Time 106 Monitor Time 107 Zone Information Transmitted from Base Station 108 Transmitted from Base Station Zone information

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shingo Murakami 1-1-6 Uchisaiwaicho, Chiyoda-ku, Tokyo Nihon Telegraph and Telephone Corporation (72) Inventor Settsuko Kondo 1-16 Uchiyuki-cho, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation

Claims (1)

[Claims] 1. A mobile communication system in which a service area is composed of a plurality of zones, and a base station and a mobile station provided in each zone are connected by a wireless line, wherein the wireless line has a frame by a plurality of time slots. The mobile station is a time division multiplex line configured to make a call using one time slot for each frame and repeat transmission and reception sequentially for each frame, and further, a control channel of a frequency different from that for communication is common to each zone. The base station of each zone uses a time slot which is the control channel and is different from the control signal transmission time slot of another base station, and a predetermined period T which is an integral multiple of the length of the frame is set to a constant value. The first cycle (T +
[alpha]) and the second cycle (T- [alpha]) alternately, the mobile station periodically transmits its own zone information, and the mobile station monitors the control channel in a time slot that is not used during a call and A zone selection method in channel switching during a call, characterized in that a transfer destination zone is determined based on a reception situation.