JPH07212821A - Radio channel assigning method - Google Patents

Abstract

PURPOSE:To improve frequency use efficiency for channel assignment of mobile communication. CONSTITUTION:In a time division multiplexing/multiple access system (TDMA /TDD), a base station which retrieves idle channels compares a level U1 of the interference wave received by the slot of the radio channel, which the base station will use for transmission, and a level U2 of the interference wave received by the slot, which a mobile station as the other party of communication will assign for transmission, with each other and raises a priority level fp of this channel or the frequency including this channel in the case or U1>U2 put reduces it in the case of U1(U2 and successively retrieves idle channels in the order from the channel or the frequency having the highest priority in response to a request of channel assignment.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses the same frequency for time division multiplexing / multiple access (TDMA / TDD) communication.
In addition, the base station performs independent distributed control, and TDM between base stations
The present invention relates to a method of allocating channels so that the A / TDD frame is asynchronous and channels are dynamically allocated as needed so that frequency utilization efficiency is increased and a call loss rate is reduced.

[0002]

2. Description of the Related Art Conventionally, as shown in the channel allocation detection flow of FIG. 6, there is a prescribed value of an interference wave level in a channel (slot) to be transmitted by a mobile station and a channel (slot) to be transmitted by a base station. The following free channels (27, 28) are searched randomly or in order (8
0), the channel was assigned. At this time, the channel cannot be allocated even if one of 27 and 28 satisfies the condition but the other does not. In such a state, the transmission power transmitted from the base station is generally high, or the antenna gain of the base station is higher than the antenna gain of the mobile station, or the antenna height of the base station is higher than the antenna height of the mobile station. Due to one or more of these reasons such as high gain, the level of the radio wave from the base station is high when it becomes an interference wave.

[0003]

As described above, in the conventional channel allocation, as shown in FIG. 1, the base station 3 of the cell 1 of 1 is used.
If the transmission timing from the base station 4 of the cell 2 of 2 is the same as the transmission timing from the base station 4, the desired wave source is the base station even if the interference wave source is the base station 4 as shown in FIG. Communication can be performed if the wave-interference wave ratio can secure the required value.

On the other hand, when the transmission timing from the base station 3 of the cell 1 of 1 and the transmission timing of the base station 4 of the cell 2 of 2 do not match, as shown in (2) of FIG. The signal 11 is interfered by the downlink signal 10 from the base station 4 and communication becomes impossible. At this time, since the mobile station 6 is transmitting in the cell 2 and the base station 4 is not transmitting at the timing of transmitting the downlink signal from the base station 3 to the mobile station 5, the problem is that the interference wave level is low. Absent. In this way, even if the downlink channel satisfies the required desired-interference ratio, the upstream channel may not satisfy the desired-interference ratio, and the channel cannot be used. It was inferior. The same applies to the interference from cell 1 to cell 2.

An object of the present invention is to improve frequency utilization efficiency in mobile communication channel allocation.

[0006]

The feature of the present invention for achieving the above object is to provide a wireless mobile station by time division multiplexing / multiple access (TDMA / TDD) via two or more wireless base stations. In a wireless channel allocation method for searching for an empty channel for mobile wireless communication that performs two-way communication between two base stations, in a base station searching for an empty channel, the interference wave received in the slot of the wireless channel to be transmitted by the base station The level (U1) is compared with the level (U2) of the interference wave received in the slot to be allocated for transmission by the mobile station that is the communication partner of the base station, and when the comparison result is U1> U2 The priority (fp) of the channel or slot is increased, and conversely, when U1 <U2, the priority (fp) of the channel or slot is decreased to reduce the channel allocation. It is the channel assignment method of searching sequentially idle channel from the highest priority channel when there is determined.

Instead of determining the priority for each channel, the priority may be determined for each frequency including the channel, and the channel allocation may be performed from the channel having the higher priority frequency.

[0008]

The present invention preferentially searches for a channel as shown in FIG. 1 (1) and raises the priority of the channel to make a request for channel allocation, that is, when an incoming call or an outgoing call is made. Assign to. On the other hand, the channel shown in (2) of the figure has its priority lowered and is not assigned as long as there is another channel to be assigned.

FIG. 2 is a diagram for explaining the operation of the present invention.
When the frame phases of the cell 1 and the cell 2 are aligned, that is, when they are synchronized, even if the base station 1 transmits at slot number 1, the interference wave 17 to the cell 2 is added to the mobile station 2, but the desired wave. Since the level of 18 is also a downlink signal from the base station 2, it is strong and communication is possible. Also, mobile station 2 with slot number 5
Even if the interference wave 20 to the cell 1 is transmitted to the base station 1 even if it is transmitted, the interference wave source is the mobile station even though the level of the desired wave 19 is the upstream signal from the mobile station 1. Communication is possible because the level is low. In this way, bidirectional communication can be performed.

[0010]

FIG. 3 is a diagram for explaining the flow of channel allocation according to the embodiment of the present invention.

In FIG. 3, 20 to 23 are algorithms for defining the priority (fp) of the channel to be assigned.
22 and 23 raise or lower the priority (fp) for each channel. 24 determines whether there is a channel request. 25 determines whether there is a channel that has not been searched at the time of channel allocation. 26 searches for the highest priority channel among the channels not searched. 27 to 28 determine whether or not the interference wave level of the channel searched for in 26 is less than or equal to a specified value. When there is no unsearched channel and channel allocation is not possible, 29 notifies that effect.

When there is no request for free channel allocation, the magnitude relationship between the interference wave level of the uplink channel and the interference wave of the downlink channel is compared for each channel, and the priority of the channel is updated (20, 21, 22, 23). ). When there is a channel allocation request (24), a high priority channel is selected at 26 based on the priorities obtained at 20 to 23, and it is determined at 27 and 28 that the channel is a free channel, and then a free channel is obtained. If it can be determined that, the channel is assigned. If it is not an empty channel, the same determination is made for the next-priority channel, and the process is continued until the channel can be assigned. If all channels are searched and there is no free channel, a determination to that effect is made at 25 and the call is lost (29), and the priority is updated until the next channel allocation request is made.

FIG. 4 is a diagram for explaining the flow of channel allocation according to another embodiment of the present invention. In FIG. 3, allocation is performed for each TDMA time-division slot, whereas in FIG. 4, all burst slots are allocated for each frequency. Figure 4
3 is different from the embodiment of FIG. 3 in that the priority for each frequency is raised or lowered by 77 and 78. When there is no request for vacant channel allocation, the magnitude relationship between the interference wave level of the uplink channel and the interference wave of the downlink channel is compared for each frequency, and the priority of the channel is updated (20, 21, 77, 78). When there is a channel allocation request (24), 20 to 21,
Based on the priorities obtained in 77 to 78, the channel (slot) in the high-priority frequency is selected in 26, and it is confirmed that the interference wave is lower than the specified value and is an empty channel 27, 28.
If it can be determined that the channel is an empty channel after the determination in step 2, that channel is assigned. If it is not an empty channel, the same judgment is made for another slot having the same frequency, and if it is judged as an empty channel, that channel is assigned. If a channel that can be assigned is not found within that frequency, the same determination is made for the next frequency, and the process is continued until the channel can be assigned. When all channels are searched, if there is no free channel, the determination is made at 25 and the call is lost (29), and the priority is updated until the next channel allocation request is made.

[0014]

As described above, according to the present invention, when the frames between the base stations are asynchronous, the channel having the smallest phase error with the frame of the base station of the interference wave source is preferentially allocated, so that the frequency is assigned. The use efficiency of is increased. For example, in (1) of FIG. 5A, the phases of the base station 1 and the base station 2 are 180 degrees out of phase, and when four slots cause interference, two base stations can use only four channels in total. In (2), when the phases of the base station 1 and the base station 2 are offset by 135 degrees and interference occurs in 3 slots, a total of 5 channels can be used by the two base stations. Further, (3) in FIG. 5B
Then, the phases of base station 1 and base station 2 are 90 degrees out of phase,
Slots cause interference, and two base stations can use a total of 6 channels. In (4), the phases of the base station 1 and the base station 2 are shifted by 45 degrees, and one slot causes interference.
One base station can use a total of 7 channels. Thus, as the phase difference becomes smaller, more channels can be used, and in (5) of FIG. 5C, all 8 channels can be used. In the present invention, channels having a small phase difference are preferentially used in this manner, so that efficient use is possible.

[Brief description of drawings]

FIG. 1 is a diagram illustrating a situation in which channel usage efficiency, that is, frequency usage efficiency is deteriorated when frames are asynchronous, and the concept of the present invention.

FIG. 2 is a diagram illustrating an operation obtained when a channel having a frame phase aligned with a frame phase of a base station of an interference wave source is selected in the present invention.

FIG. 3 is a flowchart illustrating an example of the present invention.

FIG. 4 is a flow chart illustrating another embodiment of the present invention.

FIG. 5A is a diagram illustrating an effect of the present invention.

FIG. 5B is a diagram illustrating an effect of the present invention.

FIG. 5C is a diagram illustrating an effect of the present invention.

FIG. 6 is a diagram illustrating a conventional channel allocation algorithm.

[Explanation of symbols]

1 cell 1 2 cell 2 3 base station forming cell 1 4 base station forming cell 2 5 mobile station communicating with base station 3 in cell 1 6 mobile station communicating with base station 4 in cell 2 7 base Downstream signal from station 3 to mobile station 5 Interference wave from base station 4 to mobile station 5 9 Downstream signal from base station 4 to mobile station 6 same as 8 10 From base station 4 to base station 3 Interference wave 11 Signal from mobile station 5 to base station 12 Timing of transmission and reception of mobile station 1 in slot R Reception timing T Transmission timing 13 Timing of transmission and reception of base station 1 in slot 14 Within slot Timing of transmission and reception of mobile station 2 Timing of transmission and reception of base station 2 within slot 16 Desired wave 17 signal from base station 1 to mobile station 1 Interference wave from mobile station 2 to base station 1 18 Base Station 2 to mobile station Signal from the mobile station 1 to the base station 1 desired wave 20 interference signal from the mobile station 2 to the base station 21 signal from the mobile station 2 to the base station 2 desired wave 30 within the slot Timing of transmission and reception of mobile stations 1 and 2 Timing of reception after transmission of base station 1 in 31 slot 32 Timing of transmission and reception of base station 2 in slot 33 Transmission and reception of mobile stations 3 and 4 in slot Timing 34 transmission and reception timings of mobile stations 1 and 2 in slot 35 transmission and reception timing of base station 1 in slot 36 transmission and reception timing of base station 2 in slot 37 mobile station 3 in slot ~ 5 timing of transmission and reception 38 Timing of transmission and reception of mobile stations 1 to 3 in slot 39 Timing of transmission and reception of base station 1 in slot 40 40 Timing of transmission and reception of the ground station 2 Timing of transmission and reception of the mobile stations 4 to 6 in the slot 42 Timing of transmission and reception of the mobile stations 1 to 3 in the slot 43 Transmission and reception of the base station 1 in the slot 43 Timing of transmission and reception of base station 2 in slot 44 Timing of transmission and reception of mobile stations 4 to 7 in slot 46 Timing of transmission and reception of mobile stations 1 to 4 in slot 47 Base in slot Timing of transmission and reception of station 1 Timing of transmission and reception of base station 2 in 48 slots 49 Timing of transmission and reception of mobile stations 5 to 8 in slot 50 Desired by signal from mobile stations 1 and 2 to base station Wave 51 Signal from the base station 1 to the mobile stations 1 and 2 Desired wave 52 Interference wave from the base station 2 to the base station 53 Interference wave from the base station 1 to the base station 54 Base station Signal from the mobile station 3 to 4 to the desired wave 55 signal from the mobile station 3 to 4 to the base station 2 desired wave 56 signal from the mobile station 1 to 2 to the base station 1 desired wave 57 move from the base station 1 Desired wave with signals to stations 1 and 2 58 Interference wave from base station 2 to base station 1 59 Interference wave from base station 1 to base station 2 60 Desired wave with signal from mobile stations 3 to 5 61 desired signal from base station 2 to mobile stations 3 to 5 62 desired signal from mobile station 1 to base station 1 63 desired signal from base station 1 to mobile stations 1 to 64 Interference wave from station 2 to base station 1 65 Interference wave from base station 1 to base station 2 66 Desired wave as a signal from mobile stations 4 to 6 to base station 2 67 From base station 2 to mobile stations 4 to 6 Desired signal 68 Signal from mobile stations 1 to 3 to base station 1 Desired signal 69 Signal from base station 1 to mobile stations 1 to 3 Desired wave 70 Interference wave from base station 2 to base station 1 71 Desired wave with signal from mobile stations 4-6 to base station 2 72 Desired wave with signal from base station 2 to mobile stations 4-7 73 Mobile station 1 ~ 4 signal from base station 1 to desired wave 74 Signal from base station 1 to mobile stations 1 to 4 desired wave 75 Signal from mobile station 5-8 to base station 2 desired wave 76 Move from base station 2 Desired wave by signals to stations 5 to 80 The order of channels to be searched is determined by the conventional channel allocation algorithm.

Claims (2)

[Claims] 1. An empty channel for mobile radio communication for performing bidirectional communication between radio mobile stations by time division multiple access / multiple access (TDMA / TDD) via two or more radio base stations. In the radio channel allocation method, the level (U1) of the interference wave received in the slot of the radio channel to be transmitted by the base station and the mobile station that is the communication partner of the base station The levels of interference waves (U2) received in slots to be allocated for transmission are compared. When the comparison result is U1> U2, the priority (fp) of that channel or slot is increased, and conversely U1 < When it is U2, the priority (fp) of the channel or slot
The channel allocation method is characterized in that when a channel allocation request is made, an empty channel is sequentially searched from a channel having a higher priority. 2. A free channel for mobile radio communication for performing bidirectional communication between radio mobile stations by time division multiple access / multiple access (TDMA / TDD) via two or more radio base stations. In the wireless channel allocation method, in a base station searching for an empty channel, the level (U1) of the interference wave received in the slot of the wireless channel that the base station is trying to transmit and the mobile station that is the communication partner of the base station are The levels of interference waves (U2) received in slots to be assigned for transmission are compared, and when the comparison result is U1> U2, the priority (fp) of the frequency including the slots is increased, and conversely U1 When <U2, the priority (fp) of the frequency is lowered, and when a channel allocation request is made, empty channels are sequentially searched from the channels in the higher priority frequencies. A channel allocation method characterized by searching.