JP3460133B2 - Channel quality management system - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to TDMA (Time
Division Multipile Acces
s) on the channel quality control system in a communication.
The present invention relates to a technique for improving communication quality when the communication quality deteriorates during communication.

[0002]

2. Description of the Related Art In recent years, multimedia services have attracted attention in access wireless communication. In multimedia wireless communication, frequency utilization efficiency is improved by providing a service with a variable transmission rate according to the service. In the TDMA method, in order to make the transmission rate variable, the number of channels assigned to one user can be changed according to the user information rate to realize multimedia communication. On the other hand, in the TDMA method, when quality deterioration occurs during communication, the communication quality for the user can be maintained by switching the time slot in use to another time slot.

[0003]

When one user uses a plurality of channels, conventionally, all the time slots that need to be switched are switched to other time slots due to deterioration of communication quality. Therefore, if the number of empty time slots that can be switched to is smaller than the number of switch source time slots, communication will continue without switching all time slots that have deteriorated in quality, making it difficult to maintain communication quality. become.

In the background described above, the present invention determines the switching source time slot in which the quality deterioration has occurred in accordance with the number of empty time slots to be switched to.
Channel quality control sheet which can improve the communication quality
The purpose is to provide a stem .

[0005]

The present invention comprises a control station having a time slot control means, a reception quality measuring means and a transmitting / receiving means, and a terminal having the transmitting / receiving means.
In the channel quality control system that communicates by A method,
A plurality of time slots are allocated to one user between the control station and the terminal, and the control station measures the reception quality measuring means when the communication quality deterioration is detected by the reception quality measuring means. Further comprising switching priority order determination means for determining the priority order for a plurality of time slots of one user based on communication quality for each time slot,
The time slot control means is characterized in that the time slot is switched based on the priority order according to the availability of the time slot with no communication quality deterioration. Further, the present invention comprises a control station having a time slot control means and a transmission / reception means, and a terminal having a reception quality measurement means and a transmission / reception means. In the meantime, a plurality of time slots are assigned to one user, and when the reception quality measuring means detects communication quality deterioration, the terminal determines the communication quality for each time slot measured by the reception quality measuring means. Based on the priority order, a priority order is determined for a plurality of time slots of one user, and a switching priority order determining means for transmitting a time slot switching request to the control station based on the priority order is further included. The means determines the time indicated by the received switching request according to the availability of time slots without deterioration of communication quality. And switches the slot. Further, according to another embodiment of the present invention, the switching priority order determining means, based on the communication quality in a plurality of time slots of one user measured by the reception quality measuring means,
First, the priority order is determined by the number of errors in data block units, and secondly, for time slots having the same priority order, the priority order is determined by the number of times error correction cannot be performed, and the same priority order is set. Thirdly, it is also preferable that, for a certain time slot, the priority is determined by the number of error bits.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The configuration of an embodiment of the present invention is shown in FIG.

The present invention is a TDMA communication system in which the number of time slots is dynamically and variably assigned according to a service, and is composed of a control station that dynamically allocates a used channel and a terminal that communicates using the assigned time slots. To be done.

The control station has a transmitting / receiving unit 10 for transmitting and receiving signals, a received signal quality measuring unit 12 for monitoring communication quality, and a switching priority for determining a switching priority order based on a result measured by the received signal quality measuring unit. The order determination unit 14, the signal processing unit 18 that processes messages such as the switching priority or the instruction of the time slot of the switching destination, manages the use status of the time slot, and requests the user to start new communication or switch the time slot. A time slot control unit 16 that dynamically allocates necessary time slots and indicates available time slots to terminals.

The terminal side is composed of a transmitting / receiving section 20, a received signal quality measuring section 22, a switching priority order determining section 24, and a signal processing section 26, excluding the time slot control section of the control station.

In bidirectional communication, the communication quality can be monitored on the terminal side and the control station side, respectively. Here, the case where the deterioration of communication quality is detected by the control station, the priority order of the switching source time slot is selected and the switching destination time slot is selected by the control station, and the switching instruction is transmitted to the terminal is the control station-led switching. . On the contrary, the case where the terminal side detects the deterioration of the communication quality and transmits the switching request to the control station is referred to as terminal-led switching.

The control station initiative type switching processing procedure is shown in FIG. 2A and FIG.
B shows the terminal-led switching processing procedure in FIGS. 3A and 3B.

As shown in FIG. 2A, in the control station-led switching process, when the control station detects the deterioration of the communication quality during communication (31), based on the result measured by the received signal quality measuring unit. The switching priority determining unit determines the switching priority (32).

The switching priority is determined from the following four parameters. (1) Number of errors in data block units (2) Number of occurrences of error correction impossible (3) Number of error bits (4) Received signal level

(1) shows the result of counting whether or not there is an error in one block with a fixed number of bits as one unit and how many times it is judged as an error during the measurement time.
(2) shows the number of times that an error occurs beyond the correction capability when an error correction code is used and error correction is impossible during the measurement time. (3) shows the number of bits for which the error correction is performed during the measurement time when the error correction code is used. (4) shows the average reception level of the time slot.

The switching priority order for selecting the switching source time slot for performing the switching is the numerical order of (1) to (3) above, where (1) has the highest switching priority and (3) has the highest. Low. Further, when switching occurs under the same conditions, the larger the value of the quality measurement result such as the number of errors, the higher the priority.

Further, if the quality measurement results are the same, a time slot having a low received signal level is given higher priority.

When the received signal level is lower than a certain level, it is unlikely that the quality is deteriorated due to interference, and therefore quality improvement due to time slot switching cannot be expected. Therefore, in this case, switching is not performed.

Even if all the items (1) to (4) cannot be measured, the priority can be determined by measuring one or more items.

Further, the presence / absence of interference is monitored with respect to an empty time slot, and if it is available, it is selected as a switching destination time slot (34). A switching instruction signal for notifying the terminal of the switching source time slot, the switching priority order, and the switching destination time slot is transmitted to the terminal via the signal processing unit and the transmitting / receiving unit.

After that, in order to start communication using the switching destination time slot, switching processing such as establishing synchronization of a new time slot and disconnecting synchronization of the switching source time slot is performed (35), and these processing ends normally. After that, the communication using the switching destination time slot is started by receiving (38) the switching completion signal for notifying the switching completion from the terminal. When the switching process fails, a signal notifying the switching failure is transmitted to the terminal (37) and the communication is continued using the switching source time slot.

In the terminal, as shown in FIG. 2B, communication using the switching destination time slot is performed by receiving a switching instruction signal for notifying the switching source time slot, the switching priority, and the switching destination time slot from the control station (41). In order to start synchronization, switching processing such as establishment of synchronization of a new time slot, interference detection and disconnection of synchronization of a switching source time slot (4
2) is performed, and after these processes are completed normally, a switching completion signal for notifying switching completion is transmitted to the control station to start communication using the switching destination time slot. When the switching process fails, a signal notifying the switching failure is transmitted to the control station (44) and the communication is continued using the switching source time slot.

As shown in FIG. 3A, in the terminal-initiated switching process, the control station monitors the presence or absence of interference in the empty time slot by receiving the switching request signal (51), and switches if it is available. It is selected as the destination time slot (52). A switching instruction signal for notifying the terminal of the switching source time slot and switching priority order designated by the terminal and the switching destination time slot selected by the control station is transmitted to the terminal via the signal processing unit and the transmitting / receiving unit. As for the switching priority order, as described above, the switching priority order of the switching source time slot can be given based on the same concept as the control station.

After that, in order to start communication using the switching destination time slot, switching processing (54) such as establishing synchronization of a new time slot and disconnecting synchronization of the switching source time slot is performed, and these processing ends normally. After that, the communication using the switching destination time slot is started by receiving the switching completion signal for notifying the switching completion from the terminal.
When the switching process fails, a signal for notifying the switching failure is transmitted to the terminal (56) and the communication is continued using the switching source time slot.

In the terminal, as shown in FIG. 3B, when the deterioration of the communication quality is detected during the communication (61), the switching priority order determination unit sets the switching priority order based on the result measured by the received signal quality measurement unit. Determine (62). A switching request signal for notifying the switching source time slot and the switching priority is transmitted to the control station (63). Also, upon receiving a switching instruction signal notifying the switching source time slot, the switching priority order, and the switching destination time slot from the control station (64), communication using the switching destination time slot is started, so that synchronization of a new time slot is established. By performing switching processing (65) such as interference detection and synchronous disconnection of the switching source time slot, and after the processing is normally completed, a switching completion signal for notifying switching completion is transmitted to the control station (67). Communication using the switching destination time slot is started. When the switching process fails, a signal for notifying the switching failure is transmitted to the control station (68) and communication is continued using the switching source time slot.

[0025]

The effect of the present invention is shown in FIG. FIG. 4 shows the normalized improvement rate of communication quality with respect to the number of empty slots that can be designated as the switching destination. As shown in FIG. 4, the method of switching all the slots to be switched can improve the communication quality only when there are empty slots more than the number of the slots to be switched. It can be seen that the improvement can improve the communication quality.

[Brief description of drawings]

FIG. 1 is a diagram illustrating an example of the present invention.

FIG. 2A is an explanatory diagram of a control station of a control station initiative type switching processing procedure according to the present invention.

FIG. 2B is an explanatory diagram of a terminal of a control station initiative type switching processing procedure according to the present invention.

FIG. 3A is an explanatory diagram of a control station of a terminal-led switching processing procedure according to the present invention.

FIG. 3B is an explanatory diagram of a terminal in a terminal-led switching processing procedure according to the present invention.

FIG. 4 is a diagram illustrating an effect of the present invention.

[Explanation of symbols]

10, 20 Transceiver 12, 22 Received signal quality measurement unit 14, 24 Switching priority order determination unit 16 Time slot control unit 18, 26 Signal processing unit

─────────────────────────────────────────────────── ─── Continuation of front page (56) Reference JP-A-4-68722 (JP, A) JP-A-59-171331 (JP, A) JP-A-7-240959 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) H04J 3/17

Claims (3)

(57) [Claims] 1. A channel quality management system, comprising a control station having a time slot control means, a reception quality measuring means and a transmitting / receiving means, and a terminal having the transmitting / receiving means, wherein the channel quality management system communicates in a TDMA system, wherein the control station and the terminal are provided. During this period, a plurality of time slots are allocated to one user, and when the reception quality measuring unit detects communication quality deterioration, the control station is configured to measure the time slots measured by the reception quality measuring unit. A switching priority order determining means for determining a priority order for the plurality of time slots of the one user based on each communication quality; and the time slot control means is a time slot availability state without communication quality deterioration. Channel product, wherein the time slots are switched based on the priority order according to Management systems. 2. A channel quality management system comprising a control station having a time slot control means and a transmission / reception means, and a terminal having a reception quality measurement means and a transmission / reception means, wherein the control station and the terminal are connected to each other. During this period, a plurality of time slots are assigned to one user, and when the reception quality measuring unit detects communication quality deterioration, the terminal is provided with each time slot measured by the reception quality measuring unit. Further includes a switching priority order determining means for determining a priority order for the plurality of time slots of the one user based on the communication quality of the user and transmitting a time slot switching request to the control station based on the priority order. However, the time slot control means of the control station receives data according to the availability of time slots without deterioration of communication quality. A channel quality management system characterized by switching the time slot designated by the received switching request. 3. The switching priority determining means is based on the communication qualities of the one user in the plurality of time slots measured by the reception quality measuring means, and firstly, is prioritized by the number of errors in data block units. It decides the order, and for timeslots with the same priority, the second
In addition, the priority order is determined by the number of times that error correction cannot be performed, and for time slots with the same priority order,
Thirdly, the channel quality management system according to claim 1 or 2, wherein the priority is determined according to the number of error bits.