JP3620781B2 - Channel assignment device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention performs high-accuracy channel estimation based on received signals in a mobile communication system using a TDD (Time Division Duplex) method, and realizes transmission diversity, open-loop transmission power control, adaptive array antenna, and the like with high accuracy. The present invention relates to a channel assignment apparatus for
[0002]
[Prior art]
The TDD scheme is a radio access scheme that realizes uplink and downlink by time-sharing the same frequency, and is generally used in multiplexing schemes such as TDMA (Time Division Multiple Access) and CDMA (Code Division Multiple Access). ing. A characteristic of the TDD scheme is that the frequency selectivity fading can be estimated from the received signal because the uplink and downlink frequencies are the same.
[0003]
There are two typical techniques that take advantage of this feature: transmission diversity and open-loop transmission power control. Each will be described.
[0004]
First, transmission diversity will be described. In mobile communications, it is a multi-wave propagation path because it is reflected, diffracted, scattered, etc. by the topography and features around the mobile station. In this case, a large number of waves coming from various directions interfere with each other, and instantaneous value fluctuations (Rayleigh fading) occur. Since the envelope of this fading received wave falls to near the thermal noise level of the receiver, it becomes an obstacle to realizing high-quality transmission. As a technique for reducing this fading, there is diversity reception using two or more received waves. For example, a diversity wave is a method in which a reception wave that varies independently is obtained by separating two antennas spatially, and quality degradation is reduced by combining two reception waves or selecting a reception wave having a high reception level. It is reception. In order to perform diversity reception, generally, a plurality of receivers are required, which is not suitable for downsizing the apparatus. However, in the FDD (Frequency Division Duplex) system in which the frequency differs between the uplink and the downlink, since the fading is different, reception diversity is performed in the mobile station and the base station. On the other hand, in the TDD scheme, since transmission and reception frequencies are the same, transmission diversity is performed in which diversity reception is performed and transmission is performed from an antenna having a high reception level. In general, transmission diversity is performed in a base station for the purpose of downsizing a mobile station.
[0005]
Next, open loop transmission power control will be described. In mobile communications, transmission power control is performed for the purpose of reducing power consumption of mobile stations and reducing the level of interference (interference power) with other mobile stations and base stations. In particular, in the CDMA system, the accuracy of transmission power control greatly affects the communication capacity. In FDD systems with different uplink / downlink frequencies, closed loop transmission power is generally used to notify the transmission side of the increase / decrease of the desired signal power based on the received power or the ratio between the received desired signal power and the interference power. ing. On the other hand, in the TDD scheme, the uplink / downlink frequencies are the same and the propagation path can be estimated, so that open-loop transmission power control for increasing / decreasing the transmission power based on the reception power can be applied. Open-loop transmission power control is generally applied to mobile stations. However, when the transmission power is changed based on the reception power of a common control channel such as a broadcast channel where the transmission power is constant, There are two methods for changing the transmission power based on the reception power.
[0006]
An adaptive array antenna that not only improves the reception performance of the uplink by taking advantage of the TDD scheme but also improves the reception performance of the downlink is proposed in IEICE Technical Report RCS98-72. ing.
[0007]
FIG. 14 is a flowchart showing an example of channel assignment processing in the conventional TDD scheme. This process is a process for assigning a channel to the uplink from the mobile station to the base station. In the conventional channel assignment processing, as shown in FIG. 14, first, in step S1201, the base station detects an uplink free channel based on the interference level. If the interference level is below a certain threshold level, it is determined that the channel is an empty channel. A table of free channels detected in step S1202 is created. When a channel allocation request is received from the mobile station (MS) (step S1203), the base station pays out and allocates a channel based on a table of free channels (step S1204). The priority order of channel payout is generally the order in which the detected interference level is low or detected.
[0008]
In a conventional TDD system, for example, PHS, the uplink and downlink are paired with both frequency channel and time slot. Therefore, the uplink channel is also determined by determining the downlink channel. Become.
[0009]
[Problems to be solved by the invention]
As described above, in the TDD scheme, transmission diversity, open-loop transmission power control, adaptive array antenna, and the like are important technologies from the viewpoints of downsizing the mobile station and simplifying control. However, both technologies are caused by the fact that the propagation path can be estimated from the received signal. When the interval between reception and transmission is large, the accuracy of each deteriorates, and as a result, the communication quality is reduced. There was a problem of lowering.
[0010]
In particular, when the moving speed of the mobile station is fast and the fading frequency is large (when the fading period is short), the accuracy degradation is significant. On the other hand, when the moving speed is slow and the fading frequency is small, the accuracy does not deteriorate so much.
[0011]
An object of the present invention is to perform appropriate channel assignment in a mobile communication system using the TDD scheme, taking into account the temporal relationship between the channel used for reception and the channel used for transmission, and the fading frequency of the mobile station. It is to be able to perform highly accurate propagation path estimation based on. Thereby, transmission diversity, open-loop transmission power control, adaptive array antenna, and the like can be realized with high accuracy, and high-quality communication, reduction of transmission power (reduction of power consumption of the mobile station), and the like can be realized. When the traffic is relatively low, the accuracy of transmission diversity, open loop transmission power control, adaptive array antenna, etc. is greatly improved.
[0012]
[Means for Solving the Problems]
According to the first aspect of the present invention, a base station transmits a signal with a constant power to a mobile station using a channel according to the TDD scheme, and transmits the signal to the base station based on the power of the signal with the constant power received by the mobile station. In a mobile communication system for controlling the power of a signal to be transmitted, a channel allocation apparatus that allocates a channel according to the TDD scheme to an uplink from the mobile station to the base station, the mobile station out of the channels according to the TDD scheme An uplink idle channel detecting means for detecting an uplink idle channel from the mobile station to the base station, a fading frequency detecting means for detecting a fading frequency of the mobile station, and a fading frequency of the mobile station detected by the fading frequency detecting means. If it is larger than the threshold value, the uplink idle channel detected by the uplink idle channel detecting means is detected. A channel having a time slot with a small delay time from the time slot of the channel used for transmission of the signal of constant power is preferentially assigned to the uplink, and if the channel is smaller than the threshold, the uplink idle Uplink channel allocating means for preferentially allocating a channel having a time slot having a large delay time from a time slot of a channel used for transmission of the signal having a constant power among uplink vacant channels detected by the channel detecting means to the uplink. It is characterized by comprising.
[0013]
According to a second aspect of the present invention, in the channel allocating device according to the first aspect, a free downlink channel detecting means for detecting a free downlink channel from the base station to the mobile station from the channels based on the TDD scheme. And a downlink channel allocating means for allocating a downlink vacant channel detected by the downlink vacant channel detecting means to an uplink vacant channel detected by the uplink vacant channel detecting means.
[0014]
According to a third aspect of the present invention, in the channel allocating device according to the second aspect, the downlink channel allocating unit allocates the free downlink channel from a time slot of a channel used for transmitting the constant power signal. The uplink idle channel having a time slot with a small delay time is performed in order, and the downlink idle channel is allocated so that the delay time from the uplink idle channel to the downlink idle channel is minimized.
[0015]
According to a fourth aspect of the present invention, in the channel assignment device according to any one of the first to third aspects, the base station has a plurality of antennas, and uses an antenna having a high reception power among the plurality of antennas. A signal is transmitted.
[0016]
According to a fifth aspect of the present invention, in the channel assignment device according to any one of the first to third aspects, the base station has an antenna, and changes the directivity of the antenna according to the received power by the antenna. It is characterized by that.
[0017]
A sixth aspect of the present invention is the channel assignment apparatus according to any one of the first to fifth aspects, wherein the channel based on the TDD scheme is a channel based on a CDMA-TDD scheme.
[0018]
A seventh aspect of the present invention is the channel assignment apparatus according to any one of the first to fifth aspects, wherein the channel based on the TDD scheme is a channel based on the TDMA-TDD scheme.
[0019]
According to an eighth aspect of the present invention, a base station transmits a signal with a constant power to a mobile station using a channel according to the TDD scheme, and transmits the signal to the base station based on the power of the signal with the constant power received by the mobile station. In a mobile communication system for controlling power of a signal to be transmitted, a channel allocation method for allocating a channel according to the TDD scheme to an uplink from the mobile station to the base station, wherein the mobile station is selected from among the channels according to the TDD scheme. Detecting an uplink free channel from the mobile station to the base station, detecting a fading frequency of the mobile station, and if the detected fading frequency of the mobile station is greater than a threshold, Of the channels, a time slot with a small delay time from the time slot of the channel used for transmitting the signal of constant power is used. Is assigned to the uplink preferentially, and when the channel is smaller than the threshold, the delay time from the time slot of the channel used for transmitting the signal of the constant power is large among the detected uplink free channels Preferentially assigning a channel having a time slot to the uplink.
[0022]
According to the above configuration, in a mobile communication system using the TDD scheme, it is possible to perform highly accurate propagation path estimation based on a received signal. Thereby, transmission diversity, open-loop transmission power control, adaptive array antenna, and the like can be realized with high accuracy, and high-quality communication, reduction of transmission power (reduction of power consumption of the mobile station), and the like can be realized.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0024]
[First Embodiment]
The channel assignment device according to the first embodiment of the present invention assigns a channel according to the TDD scheme to an uplink from a mobile station to a base station. The base station uses a part of the channel (for example, a broadcast channel) to transmit a signal of constant power to the mobile station, and the mobile station controls the power of the signal transmitted to the base station based on the power of the received signal of constant power To do. In this embodiment, the channel allocation device is realized as a part of the base station.
[0025]
The present invention relates to the TDD system, and the access system is effective for both the TDMA-TDD system and the CDMA-TDD system. In this embodiment, the CDMA-TDD system is used as the access system.
[0026]
FIG. 1 is a diagram showing an example of a TDD frame configuration in the present embodiment. In this embodiment, 16-slot TDD is used, and it is configured such that uplink time slots (# 1 etc.) and downlink time slots (# 0 etc.) alternate. However, a configuration in which upstream time slots or downstream time slots are continuous, a configuration in which the number of upstream time slots and the number of downstream time slots are asymmetric may be employed. Since the same frequency is used in the time division manner for the uplink and the downlink in this way, techniques such as transmission diversity, open-loop transmission power control, and adaptive array antenna are possible.
[0027]
Since there are eight uplink time slots and eight downlink time slots, the number of uplink channels and the number of downlink channels are each obtained by multiplying the number of spreading codes by eight. In this embodiment, the number of spreading codes is 8 (# 1 to # 8).
[0028]
In this embodiment, a signal with a constant power is transmitted from the base station to the mobile station using a channel whose time slot is # 0 or # 8. However, it is not necessary to transmit a signal of constant power using all 16 channels whose time slots are # 0 or # 8. Moreover, you may alert | report transmission power, without transmitting the signal of fixed power.
[0029]
In this embodiment, communication for assigning one time slot and one code will be described. However, the same applies to communication for assigning a plurality of time slots or a plurality of codes.
[0030]
FIG. 2 is a diagram illustrating a configuration example of a base station including the channel assignment device according to the present embodiment. The base station 200 includes a channel allocation device 250, despreading units 210a and 210b, and spreading units 212a and 212b. Each of the despreading unit and the spreading unit is provided with the number of spreading codes, that is, eight. The channel allocation device 250 includes an interference level measurement unit 214, a free channel management unit 216, and a free channel database 218.
[0031]
FIG. 3 is a diagram illustrating a configuration example of a mobile station in the present embodiment. Mobile station 300 includes despreading section 310, spreading section 312, transmission power control section 320, power amplification section 322, reception level measurement section 324, and fading frequency determination section 354. The reception level of the received data is measured by the reception level measuring unit 324. Based on the measured value, the transmission power control unit 320 instructs the power amplification unit 322 to control the power of the transmission data spread by the spreading unit 312.
[0032]
All the components of the base station 200 and the mobile station 300 may be realized by hardware or may be realized by software, except for an antenna (not shown).
[0033]
FIG. 4 is a flowchart showing an example of channel assignment processing according to the present embodiment. First, in step S401, the base station 200 detects a free uplink channel. More specifically, the interference level measurement unit 214 of the channel assignment device 250 measures the interference level of each uplink channel based on the received signal. The free channel management unit 216 determines a channel whose measured interference level is equal to or less than the threshold value as a free channel. The measurement of the interference level and the determination of the free channel based on the measurement value can be performed outside the channel assignment device 250, and the result can be notified to the channel assignment device 250.
[0034]
In step S402, the free channel management unit 216 creates a table of detected uplink free channels.
[0035]
FIG. 5 is a diagram showing an example of a table of uplink free channels. U of U / D indicates an uplink channel, and D indicates a downlink channel. Time slot indicates a time slot. Code indicates a spreading code. When the TDMA-TDD method is used as the access method, the frequency channel corresponds to Code.
[0036]
In step S403, the free channel management unit 216 sorts the table (uplink free channel). The table is sorted based on the time difference between the uplink free channel and the channel having the constant transmission power (the channel whose time slot is # 0 or # 8), and the uplink free channel with a small time difference is placed higher. The sorted table is stored in the free channel database 218.
[0037]
FIG. 6 is a diagram showing a table of free uplink channels after sorting the free uplink channel table of FIG. The channel whose time slot is close to # 0 or # 8 comes to the upper level.
[0038]
The processes in steps S401 to S403 are periodically performed, and the table of free uplink channels is updated as needed.
[0039]
When there is an uplink channel allocation request from the mobile station (MS) 300 to the base station 200 (step S404), the base station 200 detects the fading frequency of the mobile station 300 (step S405).
[0040]
The fading frequency is detected by receiving the notification of the fading frequency determined by the fading frequency determination unit 354 of the mobile station 300. The fading frequency determination unit 354 determines the fading frequency based on the reception SIR (the ratio between the received desired wave power and the interference power) measured by the reception level measurement unit 324. The mobile station 300 transmits fading frequency information to the base station 200.
[0041]
Note that the fading frequency may be determined based on pilot symbols used for synchronous detection or based on fluctuations in received power.
[0042]
The free channel management unit 216 of the base station 200 checks whether or not the detected fading frequency is larger than the threshold value (step S406). An upper channel, that is, a channel that is temporally close to a channel having a constant transmission power is preferentially paid out and assigned (step S407). The threshold value is set to an appropriate value in consideration of the relationship between fading frequency and transmission power control accuracy. If the detected fading frequency is not larger than the threshold (below the threshold), it is far in time from the lower channel of the uplink available channel table stored in the available channel database 218, that is, the channel with constant transmission power. A channel is preferentially paid out and assigned (step S408).
[0043]
If the detected fading frequency is not greater than the threshold value, the upstream idle channel may be sorted again in descending order of the time difference from the channel with the constant transmission power, and paid out from the higher channel.
[0044]
Information on the allocated channel is transmitted to the mobile station 300. Also, the spreading code information of the assigned channel is given to the despreading sections 210a and 210b.
[0045]
Thus, when the fading frequency of mobile station 300 is large, an uplink channel that is temporally close to a channel whose transmission power is constant (downlink) is assigned to the uplink. When transmitting using the allocated uplink channel, the mobile station 300 can perform transmission power control using a downlink channel whose transmission power is temporally close to that channel and is constant. As a result, when the fading frequency is high, it is possible to avoid increasing the interval between reception and transmission, and to avoid significant deterioration in the accuracy of transmission power control.
[0046]
On the other hand, when the fading frequency of the mobile station 300 is small, even if the interval between reception and transmission increases, the accuracy of transmission power control does not deteriorate so much. An uplink channel that is distant in time is assigned. As a result, when there is a channel assignment request from another mobile station with a high fading frequency, it is possible to assign an uplink channel that is temporally close to a channel whose transmission power is constant for the uplink, and the entire mobile station The accuracy of transmission power control can be increased.
[0047]
In this embodiment, the channel allocation device 250 is realized as a part of the base station 200. However, the channel allocation device 250 is independent from the base station 200, and the determination result of the uplink free channel is moved from the base station 200 to the fading frequency determination result. It is also possible to receive from the station 300 and perform channel allocation processing and transmit the allocation result to the base station 200 and the mobile station 300. Further, the channel assignment device 250 can be realized as a part of a higher-level control device of the base station, and the channel assignment processing can be performed by the control device.
[0048]
[Second Embodiment]
The channel assignment apparatus according to the second embodiment of the present invention assigns a channel according to the TDD scheme to an uplink from a mobile station to a base station and to a downlink from the base station to the mobile station corresponding to the uplink. The base station transmits a signal of constant power to the mobile station using a part of the channel, and the mobile station controls the power of the signal transmitted to the base station based on the received power of the constant power signal.
[0049]
Also in the present embodiment, as in the first embodiment, the channel assignment apparatus is realized as a part of the base station, the CDMA-TDD method is used as the access method, and the TDD frame configuration is the same as in FIG. The number of codes is 8. Also, a signal with a constant power is transmitted from the base station to the mobile station using a channel whose time slot is # 0 or # 8.
[0050]
Also in this embodiment, communication for assigning one time slot and one code will be described, but the same applies to communication for assigning a plurality of time slots or a plurality of codes.
[0051]
FIG. 7 is a diagram illustrating a configuration example of a base station including the channel assignment device according to the present embodiment.
[0052]
Base station 700 includes channel allocation device 750, antennas 726a and 726b, transmission / reception changeover switches 728a and 728b, radio reception units 730a and 730b, radio transmission units 732a and 732b, addition units 734a and 734b, despreading units 710a, 710b, and 710c. , 710d, etc., spreading sections 712a, 712b, etc., comparison sections 736a, 736b, etc., combining sections 738a, 738b, etc., decoding sections 740a, 740b, etc., transmission antenna selection sections 742a, 742b, etc. Each of the spreading unit, the comparing unit, the combining unit, the decoding unit, and the transmitting antenna selection unit is provided with the number of spreading codes, that is, eight. The despreading unit is provided by multiplying the number of spreading codes by the number of antennas, that is, 16 pieces. The channel assignment device 750 includes an interference level measurement unit 714, a free channel management unit 716, and a free channel database 718.
[0053]
The base station 700 performs transmission diversity control. Base station 700 receives signals from the mobile station using two antennas 726a and 726b. Each of the transmission / reception selector switch, the radio reception unit, the radio transmission unit, and the addition unit is provided for each antenna. Note that the number of antennas may be more than two.
[0054]
In the present embodiment, as a method for receiving signals, a maximum ratio combining method for combining a plurality of received signals in phase is used. A plurality of signals received via the antennas 726a and 726b and the radio receiving units 730a and 730b are despread by the despreading unit 710a and the like, and in-phase synthesized by the synthesizing unit 738a and the like. Then, the data is decoded by the decoding unit to be received data. Note that the comparison unit 736a and the like specify the antenna 726a or 726b having a high reception level based on a plurality of signals. As a method for receiving a signal, an antenna selection method using an antenna reception signal with a high reception level as it is may be used instead of the maximum ratio combining method.
[0055]
For signal transmission, the transmission data is spread by the spreading unit 712a and the like, and sent to the wireless transmission unit 732a and the like via the transmission antenna selection unit 742a and the addition unit 734a. The transmission antenna selection unit 742a or the like transmits the spread transmission data to the radio transmission unit 732a or 732b corresponding to the antenna 726a or 726b having a high reception level specified by the comparison unit 736a or the like. The wireless transmission unit 732a or 732b transmits the transmitted signal to the mobile station from the corresponding antenna 726a or 726b. In this way, diversity gain can be obtained even if the mobile station does not perform diversity reception by selecting an antenna having a high reception level and transmitting a signal at the base station.
[0056]
FIG. 8 is a diagram illustrating a configuration example of a mobile station in the present embodiment. Mobile station 800 includes despreading section 810, spreading section 812, transmission power control section 820, power amplification section 822, reception level measurement section 824, free channel determination section 844, and fading frequency determination section 854.
[0057]
Except for antennas 726a and 726b, all or a part of each component of base station 700 and mobile station 800 may be realized by hardware or may be realized by software.
[0058]
FIG. 9 is a flowchart showing an example of channel assignment processing according to the present embodiment. First, in step S901, the base station 700 detects a free uplink channel and a free downlink channel.
[0059]
In detecting an uplink free channel, the interference level measurement unit 714 of the channel allocation device 750 measures the interference level of each uplink channel based on the received signal. The free channel management unit 716 determines that a channel whose measured interference level is equal to or less than the threshold value is a free channel. The measurement of the interference level and the determination of the free channel based on the measurement value may be performed outside the channel assignment device 750, and the result may be notified to the channel assignment device 250.
[0060]
Detection of a free downlink channel is performed by receiving a notification of a free channel determined by the free channel determination unit 844 of the mobile station 800. The free channel determination unit 844 determines a downlink free channel based on the reception level of the reception data measured by the reception level measurement unit 824. The mobile station 800 transmits information on downlink free channels to the base station 700.
[0061]
In step S902, the free channel management unit 716 creates a table of detected uplink free channels and a table of detected downlink free channels.
[0062]
In step S903, the free channel management unit 716 sorts the table (uplink free channel). The table is sorted based on the time difference between the uplink free channel and the channel having the constant transmission power (the channel whose time slot is # 0 or # 8), and the uplink free channel with a small time difference is placed higher.
[0063]
FIG. 10 is a diagram illustrating an example of a sorted table of uplink free channels, and FIG. 11 is a diagram illustrating an example of a table of downlink free channels. Delay 1 in FIG. 10 indicates a time difference (delay time) from a channel having a constant transmission power.
[0064]
In steps S904 to S909, a downlink idle channel is assigned to an uplink idle channel. By doing so, it becomes possible to assign a free idle channel to a downlink corresponding to the uplink simultaneously with assigning a free uplink channel to the uplink.
[0065]
Free downlink channels are allocated in order from the free uplink channel with the smallest delay1. Here, the allocation is performed so that the time difference (delay time) delay2 between the uplink idle channel and the downlink idle channel is minimized. When the delay times delay1 and delay2 are the same, it is possible to assign the uplink idle channel and the downlink idle channel so as to have the same spreading code as much as possible. Note that the same downlink idle channel is not assigned to different uplink idle channels. In addition, since traffic, communication capacity, and the like may be asymmetric between uplink and downlink, a downlink idle channel may not be assigned to an uplink idle channel.
[0066]
12 is a diagram showing a table of available channels after the downlink available channels in FIG. 11 are assigned to the available uplink channels in FIG. Since the number of free downlink channels in FIG. 11 is two less than the number of free uplink channels in FIG. 10, the free uplink channels and (# 15, # 8) A free idle channel could not be assigned to an available uplink channel.
[0067]
A table of empty channels after the downlink empty channels are allocated to the uplink empty channels is stored in the empty channel database 718.
[0068]
The processing in steps S901 to S909 is performed periodically, and the free channel table is updated as needed. Note that the processing in steps S904 to S909 takes into account the case where the TDD frame is configured such that the upstream time slot and the downstream time slot alternate as shown in FIG. Will be changed accordingly.
[0069]
When there is a channel assignment request from the mobile station (MS) 800 to the base station 700 (step S910), the base station 700 detects the fading frequency of the mobile station 800 (step S911).
[0070]
The fading frequency is detected by receiving a notification of the fading frequency determined by the fading frequency determination unit 854 of the mobile station 800. A fading frequency determination unit 854 determines a fading frequency based on the reception SIR measured by the reception level measurement unit 824. The mobile station 800 transmits fading frequency information to the base station 700.
[0071]
The free channel management unit 716 of the base station 700 checks whether or not the detected fading frequency is larger than the threshold (step S912). If the detected fading frequency is higher than the threshold, the higher channel of the free channel table stored in the free channel database 218 is checked. Channel, that is, an uplink idle channel that is close in time to a channel having a constant transmission power, and a downlink idle channel that is close in time to the uplink idle channel assigned to the uplink idle channel is preferentially paid out and assigned (step S913). If it is not larger than the threshold value (below the threshold value), the lower channel in the free channel table stored in the free channel database 218, that is, the upstream free channel far in time from the channel with constant transmission power, and A free downlink channel that is far in time from the free uplink channel assigned to the free uplink channel is preferentially paid out and assigned (step S409).
[0072]
The allocated uplink idle channel information and downlink idle channel information are transmitted to mobile station 800. Also, the information on the assigned spreading code of the free uplink channel is given to the despreading section 710a and the like, and the information of the assigned spreading code of the free idle channel is given to the spreading section 712a and the like.
[0073]
Thus, when the fading frequency of mobile station 800 is large, an uplink channel that is temporally close to a channel whose transmission power is constant (downlink) is assigned to the uplink. When transmitting using the allocated uplink channel, the mobile station 800 can perform transmission power control using a downlink channel having a constant transmission power temporally close to the channel. As a result, when the fading frequency is high, it is possible to avoid increasing the interval between reception and transmission, and to avoid significant deterioration in the accuracy of transmission power control.
[0074]
On the other hand, when the fading frequency of the mobile station 800 is small, even if the interval between reception and transmission increases, the accuracy of the transmission power control does not deteriorate so much. An uplink channel that is distant in time is assigned. As a result, when there is a channel assignment request from another mobile station with a high fading frequency, it is possible to assign an uplink channel that is temporally close to a channel whose transmission power is constant for the uplink, and the entire mobile station The accuracy of transmission power control can be increased.
[0075]
Further, when the fading frequency of mobile station 800 is large, a downlink channel that is temporally close to the uplink channel allocated to the uplink corresponding to the downlink is allocated. When transmitting using the assigned downlink channel, base station 700 can estimate the transmission characteristics of the downlink channel from the transmission characteristics of the uplink channel temporally close to the downlink channel. As a result, when the fading frequency is high, it is possible to avoid increasing the interval between reception and transmission, and to avoid significant deterioration in the accuracy of transmission diversity.
[0076]
On the other hand, when the fading frequency of the mobile station 800 is small, the accuracy of transmission diversity does not deteriorate so much even if the interval between reception and transmission increases, so the uplink allocated to the uplink corresponding to that downlink A downlink channel that is far in time from the channel is assigned. Thereby, when there is a channel assignment request from another mobile station having a large fading frequency, it is possible to assign a downlink channel that is close in time to the uplink channel assigned to the uplink corresponding to the downlink, The accuracy of transmission diversity at the base station can be increased.
[0077]
Instead of the base station 700, a base station provided with an adaptive array antenna can be used.
[0078]
FIG. 13 is a diagram illustrating another configuration example of the base station including the channel assignment device according to the present embodiment. The base station 1100 includes a channel allocation device 1150, antennas 1126a, 1126b, 1126c, etc., RF units (radio units) 1146a, 1146b, 1146c, etc., adders 1134a, 1134b, 1134c, etc., despreading units 1110a, 1110b, 1110c, etc. A spreading unit 1112 and the like, a receiving adaptive array unit 1148 and the like, and a directivity control unit 1152 and the like are provided. Each of the spreading unit, the receiving adaptive array unit, and the directivity control unit is provided with the number of spreading codes, that is, eight. Further, the despreading units are provided by the number obtained by multiplying the number of spreading codes by the number of antennas. The channel allocation device 1150 includes an interference level measurement unit 1114, a free channel management unit 1116, and a free channel database 1118.
[0079]
The base station 1100 includes an adaptive array antenna including a plurality of antennas 1126a, 1126b, 1126c, and the like. The RF unit and the adding unit are prepared for each antenna.
[0080]
The reception adaptive array unit 1148 and the like controls the directivity of the antenna to be directed toward the mobile station via the directivity control unit 1152 and the like based on the signal received by each antenna. Thereby, the antenna gain can be improved and the interference level (interference power) from other mobile stations or base stations can be reduced.
[0081]
When the channel assignment process shown in FIG. 9 is performed and the fading frequency of the mobile station 800 is large, a downlink channel that is temporally close to the uplink channel assigned to the uplink corresponding to the downlink is assigned. When transmitting using the assigned downlink channel, the base station 1100 can estimate the transmission characteristic of the downlink channel from the transmission characteristic of the uplink channel temporally close to the downlink channel. As a result, when the fading frequency is high, it is possible to avoid increasing the interval between reception and transmission, and to avoid significant deterioration of the accuracy of the adaptive array antenna.
[0082]
On the other hand, when the fading frequency of the mobile station 800 is small, the accuracy of transmission diversity does not deteriorate so much even if the interval between reception and transmission increases, so the uplink allocated to the uplink corresponding to that downlink A downlink channel that is far in time from the channel is assigned. Thereby, when there is a channel assignment request from another mobile station having a large fading frequency, it is possible to assign a downlink channel that is close in time to the uplink channel assigned to the uplink corresponding to the downlink, The accuracy of the adaptive array antenna of the base station can be increased.
[0083]
In this embodiment, channel allocation apparatuses 750 and 1150 are realized as part of base stations 700 and 1100, respectively, but are independent of base stations 700 and 1100, and the determination results of uplink free channels are shown as base stations 700 and 1100. Thus, it is possible to receive the determination result of the downlink free channel and the determination result of the fading frequency from the mobile station 800, perform channel allocation processing, and transmit the allocation result to the base stations 700 and 1100 and the mobile station 800. . Further, the channel assignment devices 750 and 1150 can be realized as a part of the higher-level control device of the base station, and the channel assignment processing can be performed by the control device.
[0084]
The channel allocation device according to the present embodiment allocates a channel to an uplink and then allocates a channel to the downlink corresponding to the uplink, but on the assumption that a channel has already been allocated to the uplink, It is also possible to assign a channel only to the downlink. In other words, regardless of the channel allocation method for the uplink, when the fading frequency of the mobile station is large, the downlink is assigned a downlink channel that is temporally close to the uplink channel allocated to the uplink corresponding to the downlink and moved. When the fading frequency of the station is small, high-accuracy channel estimation based on the received signal can be performed only by assigning a downlink channel that is far in time from the uplink channel assigned to the corresponding uplink to the downlink. Can be realized.
[0085]
【The invention's effect】
As described above, according to the present invention, it is possible to perform highly accurate propagation path estimation based on a received signal in a mobile communication system using the TDD scheme. Thereby, transmission diversity, open-loop transmission power control, adaptive array antenna, and the like can be realized with high accuracy, and high-quality communication, reduction of transmission power (reduction of power consumption of the mobile station), and the like can be realized. When the traffic is relatively low, the accuracy of transmission diversity, open loop transmission power control, adaptive array antenna, etc. is greatly improved.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an example of a TDD frame configuration according to first and second embodiments of the present invention.
FIG. 2 is a diagram illustrating a configuration example of a base station including a channel allocation device according to the first embodiment of the present invention.
FIG. 3 is a diagram illustrating a configuration example of a mobile station in the first embodiment of the present invention.
FIG. 4 is a flowchart showing an example of channel assignment processing according to the first embodiment of the present invention.
FIG. 5 is a diagram illustrating an example of a table of uplink free channels.
6 is a diagram showing a table of uplink free channels after the table of uplink free channels of FIG. 5 is sorted by the channel allocation processing example according to the first embodiment of the present invention. FIG.
FIG. 7 is a diagram illustrating a configuration example of a base station including a channel allocation device according to the second embodiment of the present invention.
FIG. 8 is a diagram illustrating a configuration example of a mobile station in the second embodiment of the present invention.
FIG. 9 is a flowchart showing an example of channel assignment processing according to the second embodiment of the present invention.
FIG. 10 is a diagram showing an example of a table of uplink free channels sorted by the channel assignment processing example according to the second embodiment of the present invention.
FIG. 11 is a diagram showing an example of a table of downlink free channels.
12 is a table showing a vacant channel table after assigning the downlink vacant channel of FIG. 11 to the uplink vacant channel of FIG. 10;
FIG. 13 is a diagram illustrating another configuration example of a base station including a channel allocation device according to the second embodiment of the present invention.
FIG. 14 is a flowchart showing an example of channel assignment processing in a conventional TDD scheme.
[Explanation of symbols]
200, 700, 1100 Base stations 210a, 210b, 310, 710a, 710b, 710c, 710d, 810, 1110a, 1110b, 1110c Despreading units 212a, 212b, 312, 712a, 712b, 812, 1112 Spreading units 214, 714, 1114 Interference level measurement unit 216, 716, 1116 Free channel management unit 218, 718, 1118 Free channel database 250, 750, 1150 Channel allocation device 300, 800 Mobile station 320, 820 Transmission power control unit 322, 822 Power amplification unit 324, 824 Reception level measurement unit 354, 854 Fading frequency determination unit 726a, 726b, 1126a, 1126b, 1126c Antenna 728a, 728b Transmission / reception changeover switch 730a, 730b Wireless reception unit 7 2a, 732b Wireless transmission unit 734a, 734b, 1134a, 1134b, 1134c Addition unit 736a, 736b Comparison unit 738a, 738b Combining unit 740a, 740b Decoding unit 742a, 742b Transmit antenna selection unit 844 Free channel determination unit 1146a, 1146b, 1146c RF Unit 1148 reception adaptive array unit 1152 directivity control unit

Claims (8)

Mobile communication in which a base station transmits a signal of constant power to a mobile station using a channel according to the TDD scheme, and controls the power of the signal transmitted to the base station based on the power of the signal of constant power received by the mobile station In the system, a channel allocation device that allocates a channel according to the TDD scheme to an uplink from the mobile station to the base station,
Uplink free channel detection means for detecting an uplink free channel from the mobile station to the base station out of channels according to the TDD scheme;
Fading frequency detection means for detecting a fading frequency of the mobile station;
When the fading frequency of the mobile station detected by the fading frequency detection unit is larger than a threshold, the channel used for transmission of the signal of the constant power among the uplink unused channels detected by the uplink idle channel detection unit A channel having a time slot with a small delay time from the time slot is preferentially assigned to the uplink, and when the channel is smaller than the threshold, the uplink idle channel detected by the uplink idle channel detection means, A channel assignment apparatus comprising: an uplink channel assigning unit that preferentially assigns a channel having a time slot having a large delay time from a time slot of a channel used for transmission of a signal of constant power to the uplink. The channel assignment device according to claim 1, wherein
Free downlink channel detection means for detecting a free downlink channel from the base station to the mobile station from the channels according to the TDD scheme;
A channel allocation apparatus further comprising downlink channel allocation means for allocating a downlink idle channel detected by the downlink idle channel detection means to an uplink idle channel detected by the uplink idle channel detection means. 3. The channel allocating device according to claim 2, wherein the downlink channel allocating unit includes an uplink having a time slot with a small delay time from a time slot of a channel used for allocating the downlink idle channel for transmission of the signal of constant power. 1. A channel allocation apparatus, which performs in order from an empty channel, and assigns the downlink idle channel so that a delay time from the uplink idle channel to the downlink idle channel is minimized. 4. The channel assignment apparatus according to claim 1, wherein the base station has a plurality of antennas, and transmits signals using an antenna having a high reception power among the plurality of antennas. Channel assignment device. 4. The channel assignment apparatus according to claim 1, wherein the base station has an antenna, and changes the directivity of the antenna in accordance with received power from the antenna. 6. The channel allocation device according to claim 1, wherein the channel based on the TDD scheme is a channel based on a CDMA-TDD scheme. 6. The channel allocation apparatus according to claim 1, wherein the channel based on the TDD scheme is a channel based on a TDMA-TDD scheme. Mobile communication in which a base station transmits a signal of constant power to a mobile station using a channel according to the TDD scheme, and controls the power of the signal transmitted to the base station based on the power of the signal of constant power received by the mobile station In the system, a channel allocation method for allocating a channel according to the TDD scheme to an uplink from the mobile station to the base station,
Detecting an uplink free channel from the mobile station to the base station from the channels according to the TDD scheme;
Detecting a fading frequency of the mobile station;
If the detected fading frequency of the mobile station is greater than a threshold, the detected uplink idle channel has a time slot with a small delay time from the time slot of the channel used for transmitting the signal of constant power When a channel is preferentially assigned to the uplink and is smaller than the threshold, a time slot having a large delay time from the time slot of the channel used for transmission of the constant power signal among the detected uplink free channels A channel allocation method comprising: preferentially allocating a channel having a channel to the uplink.

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