JP2003304576A - Base station apparatus and data transmission method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a simple TDMA wireless system adopting no multiplexer or the like. <P>SOLUTION: When a relay station 3 exists between a base station 2 and a speech area, the base station 2 schedules a slot timing of each mobile station 4, delays the scheduled slot timing of each mobile station 4 by a time for compensating a time required until a final relay station makes transfer after the base station 2 transmits data, and transmits data to each mobile station 4 according to the delayed timing slot so that the base station 2 can receive a reply from each mobile station 4 in the scheduled slot timing. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a TDMA wireless system having a plurality of communication areas, which is composed of circuit switching control devices, base stations (plural), relay stations (plural), and mobile stations (plural). is there.

[0002]

2. Description of the Related Art FIG. 9 shows a conventional TD having a plurality of communication areas.
MA (Time Division Multiple)
Access / FDD system configuration example. Figure 9
In the above, 1 is a circuit switching control device, 2 is a base station, 4 is a mobile station, and 5 is a multiplexer. Since the TDMA method is time division multiplexing, it is necessary to perform slot timing control for the mobile station at the base station. FIG. 4 is an image diagram of slot timing control. For example, one frame has 6 slots, and FIG.
When the base station A of FIG. 2 wants to transmit to the mobile station AA, it outputs voice and the like at the timing of slot A1. The mobile station AA synchronizes the slot with the signal, and when transmitting to the base station A, it transmits at the slot timing of A2. Since the base station A knows that the reply of the signal transmitted in the slot A1 returns at the timing of A2, it waits for the reply of the mobile station AA in the A2 slot. Similarly, slot B1 and slot B2 are assigned to mobile station AB. In the conventional system, a base station is required in each call area, and if there is a call area away from the circuit switching control unit, which is the center of the system, the circuit switching control unit and base station can be used as a multiplex device. It is necessary to connect with
It became a large system and an expensive system.

In FIG. 9, a base station controls slot timing of mobile stations within its own area. In addition, the circuit switching control device performs circuit switching for calls in each area. In a system with multiple call areas, the base station can be directly connected to the circuit switch controller if the call area is close to the circuit switch controller, but if the call area is far, the Multiplexers are connected between the base stations. FIG. 5 shows the operation of the frame in this case. First, the circuit switching control device transmits data to the multiplexer in frame units. Similarly, the multiplexer transmits data to the base station in frame units. The base station transmits the data to the mobile station at slot timing. The circuit switching controller, the multiplexer, and the base station are transmitted in frame units, and the final slot management is performed by the base station.

[0004]

In the conventional TDMA radio system, when there is a communication area in a place distant from the circuit switching controller as described above, a multiplexer is required between the circuit switching controller and the base station. There is a problem that the larger the communication area is, the larger the system becomes and the more expensive the system becomes.

In order to solve the above-mentioned problems, an object of the present invention is to provide a base station with a relay delay compensation circuit so that the system configuration becomes a circuit switching control device-base station-relay station-mobile station and multiplex. It is a simple and inexpensive system that does not use a device.

[0006]

A base station apparatus according to the present system uses a specific communication area as a management target communication area,
Transmission data can be transmitted to a plurality of mobile station devices existing in the management target communication area via at least one or more relay station devices, and a plurality of mobile stations existing in the management target communication area A base station apparatus that schedules data transmission timing for each mobile station apparatus by time division control of the apparatus and transmits transmission data to each mobile station apparatus based on the scheduled data transmission timing for each mobile station apparatus. The time required from the transmission of the transmission data from the station device to the transfer of the transmission data by the final relay station device is set as the relay required time, and the time for compensating the relay required time is set as the relay compensation time. , The data transmission timing of each mobile station device from the scheduled data transmission timing to the relay compensation time Delay, and transmits the transmission data to the relay compensation time delayed with each mobile station apparatus in the data transmission timing.

The base station apparatus schedules the data transmission timing for each mobile station apparatus by time division control using a predetermined unit time as a unit, and subtracts twice the relay station time from the unit time. The time is set as the relay compensation time.

A base station apparatus according to the present invention uses a specific communication area as a management target communication area, and at least one or more movable mobile relays for a plurality of mobile station apparatuses existing in the management target communication area. It is possible to transmit transmission data via a station device, and schedules data transmission timing for each mobile station device by time division control for a plurality of mobile station devices existing in the managed communication area, and the scheduled mobile station device. A base station device that transmits transmission data to each mobile station device based on the data transmission timing for each, and periodically detects the position of each mobile relay station device and detects the position of each mobile relay station device. Each time, based on the detected position of each mobile relay station device, the transmission data is transmitted from the local station device and then the transmission data is transmitted by the final mobile relay station device. Is calculated as the relay required time, the time for compensating the calculated relay required time is calculated as the relay compensation time, and the data transmission timing of each mobile station device is calculated as the scheduled data. It is characterized in that the relay compensation time is delayed from the transmission timing, and the transmission data is transmitted to each mobile station apparatus at the data transmission timing delayed by the relay compensation time.

The base station apparatus schedules the data transmission timing for each mobile station apparatus by time division control in units of a predetermined unit time, and subtracts twice the relay station time from the unit time. Time is calculated as the relay compensation time.

According to the data transmission method of the present invention, a specific communication area is set as a management target communication area, and at least one relay station apparatus is provided to a plurality of mobile station apparatuses existing in the management target communication area. The transmission data can be transmitted by the transmission, and the data transmission timing is scheduled for each mobile station device by time division control for a plurality of mobile station devices existing in the management target communication area, and the data transmission for each scheduled mobile station device is performed. A data transmission method for transmitting transmission data to each mobile station device based on timing, wherein the time required from the transmission of transmission data until the transmission of the transmission data by the final relay station device is performed is the relay required time. The time for compensating the relay required time is set as the relay compensation time, and the data transmission of each mobile station device is set. The timing, delay the scheduling data transmission timing the relay compensating time duration, and transmits the transmission data to the relay compensation time delayed with each mobile station apparatus in the data transmission timing.

In the data transmission method, the data transmission timing is scheduled for each mobile station device by time division control in units of a predetermined unit time, and a time twice the relay station time is subtracted from the unit time. The time is set as the relay compensation time.

A data transmission method according to the present invention uses a specific communication area as a management target communication area, and at least one or more movable mobile relays for a plurality of mobile station devices existing in the management target communication area. It is possible to transmit transmission data via a station device, and schedules data transmission timing for each mobile station device by time division control for a plurality of mobile station devices existing in the managed communication area, and the scheduled mobile station device. A data transmission method for transmitting transmission data to each mobile station device based on the data transmission timing for each, and periodically detecting the position of each mobile relay station device and detecting the position of each mobile relay station device. Based on the detected position of each mobile relay station device, the transmission data is transmitted by the final mobile relay station device. The time required for transmission is calculated as the relay required time, the time for compensating the calculated relay required time is calculated as the relay compensation time, and the data transmission timing of each mobile station device is scheduled. The transmission data is transmitted to each mobile station device at a data transmission timing delayed by the relay compensation time from the timing and delayed by the relay compensation time.

In the data transmission method, the data transmission timing is scheduled for each mobile station device by time division control using a predetermined unit time as a unit, and a time twice the relay station time is subtracted from the unit time. Time is calculated as the relay compensation time.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment 1. FIG. 1 shows a system configuration example of the TDMA wireless system according to the first embodiment. 1, 1, 2 and 4 are the same as in FIG.
In FIG. 1, the base station 2 is provided with a relay delay compensation circuit, so that the relay station 3 is arranged between the base station 2 and the communication area (communication area) instead of the multiplexing device in FIG.
The call area managed by each base station corresponds to the managed communication area. For example, in the base station A, the area A is the managed communication area, and in the base station B, the area B is the managed communication area. Further, as in the conventional technique, each base station schedules slot timing (data transmission timing) for each mobile station existing in the managed communication area.

FIG. 6 is a slot timing diagram when the relay delay compensation circuit is not provided. For example, when the user wants to talk with the mobile station C, the base station C transmits data in the slot C1. The arrival of this data at the mobile station C depends on the distance delay a between the base station C and the relay station B in FIG.
The distance delay c of the relay station C and the relay station device delay b of a + 2b +
Delay c minutes. When a signal is received, the mobile station synchronizes with the signal so that it can be used in any area (that is, the base station area or the relay station area), and the data is sent to the base station at the timing of slot C2 for the mobile station. Send. However, this data arrives at the base station C by the distance delay a of the base station C to the relay station B, the distance delay c of the relay station C to the relay station B, and the relay station device delay b of a + 2b + c in FIG.
Delayed by a minute, total round trip total relay transmission delay 2a + 4b
Data arrives with a delay of + 2c. Normally, the TDMA method is time division multiplexing, so that the timing at which the slot signal of the mobile station arrives at the base station is determined, and if the signal does not come within the range permitted by the timing, reception is impossible.
The delay time of a + 2b + c corresponds to the relay possession time.

The relay delay compensation circuit of the base station is a circuit that compensates the arrival time of the slot signal from the mobile station. The relay delay compensation circuit has a timing device and a memory that can store one frame of data. A schematic diagram of this relay delay compensation circuit is shown in FIG. The timing device counts the timing from the head of the slot and outputs a transmission start signal at a predetermined timing. 1 frame of memory is F
An IFO (First-In First-Out) memory is used, and one frame of data to be actually transmitted can be stored in the transmission order. When the base station transmits using this relay delay compensation circuit, (1 frame- (2a + 4b + 2
c)) Send it out late. This (1 frame-
The time (2a + 4b + 2c)) corresponds to the relay compensation time. That is, in the present embodiment, the relay compensation time is the time obtained by subtracting twice the time (relay required time) of (a + 2b + c) from the time of one frame (unit time). Then, the base station delays the slot timing for each mobile station by (1 frame- (2a + 4b + 2c)) time from the scheduled slot timing,
Data is transmitted at the delayed slot timing. FIG. 8 shows a slot timing chart in this case. As shown in FIG. 8, the base station transmission is (1 frame- (2a
+ 4b + 2c)) The timing is delayed, but the reply from the mobile station C is received at the slot timing scheduled by the base station. Therefore, since the timing structure of the frame does not change, it is possible to exchange data of the frame with another base station or the like via the circuit switching control device. That is, data is transferred between the circuit switching control device and the base station at the conventional frame timing, and the base station adjusts the slot timing for the delay of the relay station. This timing device makes it possible to change the timing, and it is possible to easily deal with the case where the communication area is changed and the position of the relay station is changed.

Embodiment 2. FIG. 3 shows a system configuration example of the TDMA wireless system according to the second embodiment. In the figure, 1, 2 and 4 are the same as in FIG. In Figure 3,
The relay station 3 is a movable mobile relay station, and the GPS
(Global Positioning System
m) It has a function. The mobile relay station moves in order to make a specific place in a call area in an emergency such as a disaster. At this time, although the distance delay changes depending on the position of the relay station, the mobile relay station notifies the base station of GPS information at regular intervals. The base station calculates the distance of each relay station based on this GPS information. Further, the time from the transmission of the transmission data from the base station to the transfer of the transmission data by the final mobile relay station, that is, the relay required time is calculated. Then, as shown in the first embodiment, a time obtained by subtracting twice the relay required time from the time for one frame (unit time) is calculated as the relay compensation time, and each movement is performed by the calculated relay compensation time. The transmission data is transmitted by delaying the slot timing of the station. The base station performs the above processing each time the mobile relay station notifies it of GPS information, and updates the relay compensation time according to the positional relationship of the mobile relay station.

In Embodiments 1 and 2, an example of the base station apparatus according to the present invention has been described.
The data transmission method according to the present invention can also be realized by the processing procedures shown in the first and second embodiments.

The features of the TDMA radio system shown in the first and second embodiments will be restated below. The TDMA wireless system according to the first embodiment includes a plurality of communication areas, a circuit switching controller, base stations (plural), relay stations (plural), and mobile stations (plural).
In the DMA wireless system, the base station compensates for the distance delay and the relay station device delay time.

The TDMA radio system according to the second embodiment is
In the system configuration described above, the relay station is a mobile station, and the relay station is provided with a GPS function, thereby periodically informing the base station of position information, and the base station automatically calculates the distance delay amount. The relay delay compensation amount is changed.

[0021]

As described above, according to the present invention, since the data transmission timing of each mobile station apparatus is adjusted by the relay compensation time, it is possible to realize a simple TDMA radio system without using a multiplexer or the like.

Further, according to the present invention, even if the relay station device is a mobile relay station device, the data transmission timing of each mobile station device is adjusted by the relay compensation time by detecting the position of the mobile relay station device. As a result, the call area can be easily changed in an emergency such as a disaster.

[Brief description of drawings]

FIG. 1 is a diagram showing a system configuration example of a TDMA wireless system according to a first embodiment.

FIG. 2 is an explanatory diagram of the contents of overall relay transmission delay.

FIG. 3 is a diagram showing a system configuration example of a TDMA wireless system according to a second embodiment.

FIG. 4 is an explanatory diagram of slot timing.

FIG. 5 is an operation explanatory diagram of a conventional TDMA wireless system.

FIG. 6 is an explanatory diagram of slot timing when there is no relay delay compensation circuit.

FIG. 7 is a schematic diagram of a relay delay compensation circuit.

FIG. 8 is an explanatory diagram of slot timing when there is a relay delay compensation circuit.

FIG. 9 is a diagram showing a configuration example of a conventional TDMA wireless system.

[Explanation of symbols]

1 circuit switching control device, 2 base stations, 3 relay stations, 4
Mobile station, 5 multiplex devices.

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 5K028 AA06 BB06 CC02 CC05 HH00                       KK01 KK12 LL12 RR02                 5K067 AA22 AA41 BB04 CC04 DD57                       EE02 EE06 EE10 EE72 JJ52                       JJ56                 5K072 AA18 AA29 BB13 BB27 CC15                       CC31 EE23 FF09 FF26

Claims (8)

[Claims] 1. A specific communication area is defined as a management target communication area, and transmission data can be transmitted to a plurality of mobile station devices existing in the management target communication area via at least one or more relay station devices. The mobile station device schedules data transmission timing for each mobile station device by time division control for a plurality of mobile station devices existing in the managed communication area, and each mobile station device is based on the scheduled data transmission timing for each mobile station device. Is a base station device that transmits transmission data to, and the time required from the transmission of transmission data from the local station device to the transfer of the transmission data by the final relay station device is defined as the relay required time, and The time to compensate the relay required time is set as the relay compensation time, and the data transmission timing of each mobile station device is A base station apparatus, which delays the relayed data transmission timing by the relay compensation time and transmits transmission data to each mobile station apparatus at a data transmission timing delayed by the relay compensation time. 2. The base station apparatus schedules a data transmission timing for each mobile station apparatus by time division control in units of a predetermined unit time, and a time twice as long as the relay station time from the unit time is set. The base station apparatus according to claim 1, wherein the subtracted time is set as the relay compensation time. 3. A specific communication area is set as a management target communication area, and transmission data is transmitted to a plurality of mobile station apparatuses existing in the management target communication area via at least one or more movable mobile relay station apparatuses. Is possible, the data transmission timing is scheduled for each mobile station device by time division control for a plurality of mobile station devices existing in the management target communication area, and based on the data transmission timing for each scheduled mobile station device. A base station device that transmits transmission data to each mobile station device, periodically detects the position of each mobile relay station device, and detects the position of each mobile relay station device each time the position of each mobile relay station device is detected. Based on the position of the relay station device, from when the transmission data is transmitted from the own station device until the transmission data is transmitted by the final mobile relay station device The required time is calculated as the relay required time, the time for compensating the calculated relay required time is calculated as the relay compensation time, and the data transmission timing of each mobile station device is calculated from the scheduled data transmission timing to the relay compensation time. The base station device is characterized in that transmission data is transmitted to each mobile station device at a data transmission timing delayed by the relay compensation time. 4. The base station apparatus schedules a data transmission timing for each mobile station apparatus by time division control in units of a predetermined unit time, and a time that is twice the relay station time from the unit time is scheduled. The base station apparatus according to claim 3, wherein the subtracted time is calculated as the relay compensation time. 5. A specific communication area is set as a management target communication area, and transmission data can be transmitted to a plurality of mobile station devices existing in the management target communication area via at least one or more relay station devices. The mobile station device schedules data transmission timing for each mobile station device by time division control for a plurality of mobile station devices existing in the managed communication area, and each mobile station device is based on the scheduled data transmission timing for each mobile station device. Is a data transmission method for transmitting transmission data to a device, and the time required from the transmission of the transmission data to the transfer of the transmission data by the final relay station device is defined as the relay required time, and the relay required time is The time for compensation is set as the relay compensation time, and the data transmission timing of each mobile station device is scheduled. A data transmission method comprising delaying the relayed data compensation timing by the relay compensation time and transmitting the transmission data to each mobile station device at the data transmission timing delayed by the relay compensation time. 6. The data transmission method schedules a data transmission timing for each mobile station apparatus by time division control in units of a predetermined unit time, and a time twice as long as the relay station time is calculated from the unit time. The data transmission method according to claim 5, wherein the subtracted time is set as the relay compensation time. 7. A specific communication area is set as a management target communication area, and transmission data is transmitted to a plurality of mobile station apparatuses existing in the management target communication area via at least one or more movable mobile relay station apparatuses. Is possible, the data transmission timing is scheduled for each mobile station device by time division control for a plurality of mobile station devices existing in the management target communication area, and based on the data transmission timing for each scheduled mobile station device. A data transmission method for transmitting transmission data to each mobile station device, wherein the position of each mobile relay station device is periodically detected, and each time the position of each mobile relay station device is detected, the detected movement of each mobile relay station device is detected. The time required from the transmission of transmission data to the final transfer of transmission data by the mobile relay station device based on the position of the relay station device Calculated as the relay required time,
The time for compensating the calculated relay required time is calculated as the relay compensation time, and the data transmission timing of each mobile station device is delayed from the scheduled data transmission timing by the relay compensation time and delayed by the relay compensation time. A data transmission method, wherein transmission data is transmitted to each mobile station device at a data transmission timing. 8. The data transmission method schedules a data transmission timing for each mobile station device by time division control in units of a predetermined unit time, and sets a time that is twice the relay station time from the unit time. The data transmission method according to claim 7, wherein the subtracted time is calculated as the relay compensation time.