JP2003032171A - Communication method, base station, terminal and communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently transmit, between a base station and a terminal, a huge amount of data produced burst-wise. SOLUTION: One downlink frame comprises a notice slot and one or a plurality of data slots. The terminal receives notice packets and data packets from the base station. The notice packet includes the use state of each data slot in downlink and uplink frames going to be sent from now, information as to a scheduled use of each data slot in the next downlink and uplink frames and information of a received state with respect to an upload packet of one preceding uplink frames. The uplink frame comprises a plurality of data slots, a download slot, an upload request slot and an ACK slot. ACK slot corresponds one to one to the data slot of the downlink frame.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication method applicable to a road-vehicle communication system for transmitting multimedia data from a base station to a vehicle and transmitting data from the vehicle to the base station. , Base stations, terminals and communication systems.

[0002]

2. Description of the Related Art As a demand for a road-vehicle communication system, there is realization of multimedia communication. In multimedia communication, a terminal often requests information and downloads multimedia data such as images and music data, and the amount of received (down) data is larger than the amount of transmitted (up) data from the terminal. There is a feature called. Therefore, in order to realize multimedia communication by the road-vehicle communication system, an access method for efficiently transmitting a large amount of burst-generated data to a terminal is required. Also,
The amount of data transmitted from the terminal is not necessarily small when transmitting image data captured by a vehicle, and it is desired to transmit data efficiently.

Conventionally, a wireless LAN (Local Area Network)
CSMA (Carrie
r Sense Multiple Access: carrier detection multiple access) method is known. This method is a method in which a station determines whether or not to transmit a frame after observing the channel usage status by carrier sense. CSMA / with some collision avoidance mechanism in addition to carrier detection
CA (CSMA with Collision Avoidance) is also known.

[0004]

In wireless communication, radio waves may not reach because of too long a distance between stations or because there are obstacles such as walls that do not allow radio waves to pass through. Stations where the signals transmitted by each other do not reach are called hidden terminals. For a hidden terminal, carrier sense does not function effectively, so that the frequency of frame collision increases in the CSMA method and the characteristics deteriorate. In road-to-vehicle communication, a vehicle-mounted antenna has relatively high directivity, and a hidden terminal problem is likely to occur. Therefore, it has been difficult to apply CSMA to road-to-vehicle communication.

Further, as a conventional wireless communication system, a pre-assign system and a polling system are known. The pre-assign method is a method in which each band divided by frequency or time is fixedly assigned exclusively for communication between a pair of stations. The polling method is a method in which a central station repeats polling by sequentially inquiring other stations of the presence or absence of a transmission frame. In road-to-vehicle communication, a vehicle moves at high speed in a cell and the number of terminals is undefined, so it is difficult to apply a pre-assignment method or a polling method.

Therefore, an object of the present invention is to provide a communication method, a base station, a terminal, and a communication system that enable smooth multimedia communication between road vehicles, for example.

[0007]

In order to solve the above-mentioned problems, the invention of claim 1 is such that the downlink from the base station to the terminal and the downlink from the terminal to the base station can be simultaneously communicated, and the downlink is The downlink frame transmitted via the uplink is composed of one or more notification slots and one or more data slots, and the uplink frame transmitted via the uplink is composed of one or more data slots, one or more request slots and a recognition response slot. In a communication method in a communication system according to the above, in response to a download request packet placed in a request slot, one or more empty frames included in a downstream frame subsequent to a downstream frame that received the download request packet The process of assigning data slots to terminals and the request slot In response to the upload request packet allocated to the terminal, a process of allocating, to the terminal, one or more empty data slots included in the upstream frames after the upstream frame that received the upload request packet Steps to be performed, usage status of each data slot of downlink frame and uplink frame, usage status of each data slot of next downlink frame and next uplink frame, and reception status for upload packet transmitted by terminal in previous uplink frame Generating a notification packet having information of
Transmitting the notification packet in the notification slot and transmitting the data packet in the data slot via the downlink, releasing the data slot allocated to the terminal when the transmission to the terminal is completed, and the uplink Via data slot, request slot,
A communication method comprising the steps of receiving a data packet, a request packet, and a recognition response packet included in each recognition response slot, and releasing the data slot assigned to the terminal when reception from the terminal is completed. is there. The invention of claim 5 is a base station which performs communication according to this communication method.

According to a second aspect of the present invention, the downlink from the base station to the terminal and the uplink from the terminal to the base station can be simultaneously communicated, and the downlink frame transmitted through the downlink is one or more notification slots and one or more notification slots. In the communication method in the communication system, in which the uplink frame transmitted through the uplink is composed of one or more data slots, one or more request slots and a recognition response slot, Information on the usage status of each data slot of the downlink frame and the uplink frame, the usage status of each data slot of the next downlink frame and the next uplink frame, and the reception status of the upload packet transmitted by the terminal in the previous uplink frame is displayed. Receiving a notification packet having A step of transmitting a request packet through the uplink request slot, and when the request packet is a download request, a data packet from the base station is received through the downlink data slot and a recognition response packet indicating the reception status. Is transmitted through the recognition response slot, and when the request packet is an upload request, the data packet is transmitted to the base station through the uplink data slot. The invention of claim 6 is a terminal for performing communication according to this communication method.

According to a seventh aspect of the present invention, the downlink from the base station to the terminal and the uplink from the terminal to the base station can be simultaneously communicated, and the downlink frame transmitted through the downlink is one or more notification slots and one or more notification slots. In a communication system in which an uplink frame transmitted through an uplink comprises one or more data slots, one or more request slots, and a recognition response slot. Means for allocating to the terminal, in response to the download request packet, one or more data slots that are included in the downlink frames subsequent to the downlink frame that received the download request packet and are empty, In response to the upload request packet placed in the request slot, the upload Means for allocating to the terminal one or more vacant data slots included in the upstream frames following the upstream frame that received the load request packet, and the respective data of the downstream frames and the upstream frames. Means for generating a notification packet having information on the usage status of the slot and the usage status of each data slot of the next downlink frame and the next uplink frame and the reception status for the upload packet transmitted by the terminal in the previous uplink frame; Sends the notification packet in the notification slot via the downlink, sends the data packet in the data slot, and releases the data slot assigned to the terminal when the transmission to the terminal is completed, and via the uplink. Data slot, request slot, recognition response slot Each of the data packet, the request packet, and the recognition response packet included in each of the terminals, and the means for releasing the data slot allocated to the terminal when the reception from the terminal is completed, the terminal receives the notification packet. And a means for transmitting the request packet through the uplink request slot, and when the request packet is a download request,
The data packet from the base station is received through the downlink data slot, the recognition response packet indicating the reception status is transmitted through the recognition response slot, and when the request packet is the upload request, the data packet is transmitted through the uplink. It is configured to transmit to the base station via the data slot,
The base station has an integrated base station, and in the downlink, the integrated base station generates data packets and notification packets modulated by the wireless modulation method, and the generated data packets and notification packets are radiated to the terminal. Is
The communication system is characterized in that the request packet, the recognition response packet, and the data packet, which are transmitted from the terminal and are modulated by the wireless modulation method, are transmitted to the integrated base station and are subjected to optical wireless conversion in the integrated base station.

According to the present invention, one or more data slots in one frame can be assigned to a certain terminal at the time of downloading, so that one data slot is assigned to one terminal in one frame. Throughput can be increased as compared with. Similarly, when uploading, 1 for each terminal
The above data slots can be assigned, and a relatively large amount of data can be uploaded from the terminal to the base station in a short time.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. The line configuration in one embodiment is composed of uplink and downlink capable of simultaneous communication, and each line is slotted. In the downlink from the base station to the terminal, at least one notification slot and one or more data slots make up one frame (hereinafter appropriately referred to as a downlink frame). The uplink from the terminal to the base station has one or more data slots, a request slot, and an acknowledge (means a recognition response.
A slot (abbreviated as ACK) constitutes one frame (hereinafter, appropriately referred to as an upstream frame). FIG. 1 shows a configuration example of a base station, and FIG. 2 shows a configuration example of a terminal.

In FIG. 1, reference numeral 1 indicates a base station. The base station 1 includes a network control unit 2 connected to a network, a data packet generation unit 3, a notification packet generation unit 4, a selector 5 for selectively outputting a data packet and a notification packet, and an output of the selector 5. The transmitter 7 included in the wireless device 6, the antenna 8 for radiating the wireless signal from the transmitter 7 toward the terminal, and the receiver 9 to which the received signal from the terminal of the antenna 8 is supplied.
And a received packet determination unit 10.

Multimedia data is transmitted from the network via the network control unit 2 to the data packet generation unit 3
And the data packet is generated by the data packet generator 3. The notification packet generator 4 generates a notification packet. Received packet determination unit 1
The received packet determined by 0 is transmitted to the network via the network control unit 2. As the network, mobile phone network, broadcasting network,
Internet or the like is possible.

The base station 1 notifies each terminal of the following information by means of a notification packet arranged in the notification slot at the beginning of each downlink frame.

First, it includes the usage status of each data slot in the downlink frame which is about to be transmitted and the information about the usage schedule of each data slot in the next downlink frame. That is, the notification packet has information about which terminal each data slot in each downlink frame is assigned to (or information about whether it is reserved). Each terminal can determine which data slot it should receive from the contents of the notification packet. If the transmission of the data packet is not completed in the downlink frame to be transmitted from now on, it is necessary to continuously transmit the rest of the data packet in the next downlink frame. Therefore, the notification packet has information about which terminal the data slot of the next frame is assigned to.

The terminal receiving the notification packet can determine which data slot data of the downlink frame should be received from the information of the notification packet. further,
The terminal receiving the data packet can determine whether or not there is a data packet to be received in the next downlink frame as well, based on the information about the next downlink frame. For example, when the transmission of the data packet is completed in this downlink frame and there is no data packet to be transmitted continuously in the next downlink frame, all the data slots not used in this downlink frame and the next downlink frame are used. The data slot becomes empty.

Secondly, the notification packet includes the usage status of each data slot in the upstream frame and information on the usage schedule of each data slot in the next upstream frame. Each terminal can determine which data slot it should use to transmit data from the content of the notification packet.

Thirdly, the notification packet includes information on the reception status at the base station for the upload packet transmitted by the terminal in the previous upstream frame. That is, the notification packet includes information on whether or not the upload packet has been normally received by the base station.

Next, a configuration example of the terminal will be described with reference to FIG. In FIG. 2, reference numeral 21 indicates a terminal. Reference numeral 22 indicates a network control unit, and a data device is connected to the network control unit 22. The data device utilizes received data or generates transmitted data. Data equipment includes mobile phone terminals, personal computers, digital broadcast receivers, digital cameras, car navigation devices, GPS (Global Po
sitioning System), display, audio system, etc. can be used.

Reference numerals 23, 24 and 25 are request packet generators connected to the network controller 22, respectively.
A data packet generator and an ACK data generator. These generators 23, 24 and 25 and the wireless device 2
A selector 26 is provided between the transmitter 26 and the transmitter 28. The data selected by the selector 26 is supplied to the transmission unit 28. A radio signal from the transmitter 28 is radiated from the antenna 29 and uploaded to the base station 1.

When a request for download or upload is issued to the terminal 21, the request packet generator 23 generates a request packet for download or upload. The data packet to be uploaded is generated by the data packet generator 24. Further, ACK data is generated by the ACK data generation unit 25.

At the time of downloading, the terminal 21 receives the notification packet and the data packet transmitted by the base station 1 via the antenna 29. The reception signal received by the antenna 29 is supplied to the reception unit 30 of the wireless device 27. The reception signal from the reception unit 30 is the reception packet determination unit 3
1 is supplied. The received packet determination unit 31 determines whether the received packet is a notification packet or a data packet.

The received packet from the received packet determination unit 31 is supplied to the data device via the network control unit 22. When a download or upload request is generated in the terminal 21, the terminal 21 receives the notification packet transmitted by the base station 1, and the request packet generation unit 23 generates a download or upload request packet according to the notification content. The request packet is transmitted to the base station using an arbitrary request slot of the upstream frame.

The above-mentioned base station 1 (FIG. 1) and terminal 21
(FIG. 2) is a base station in a road-to-vehicle communication system and
It corresponds to a terminal installed in a vehicle. Than
Specifically, it is compatible with the road-vehicle communication system as shown in FIG.
Then, the present invention can be applied. Figure 3 system
Is an integrated base station indicated by reference numeral 41 and reference numeral 4
Two ₁, 42₂, And the reference numeral 43
₁, 43₂, ..., and the integrated base station 41 and optical fiber
42₁, 42₂, ... Multiple local base stations connected by
Composed of and. Local base station 43₁, 43₂・ ・ ・
Are installed at predetermined intervals along the road, and the vehicle 4
Road-to-vehicle communication with the terminal installed in 4 is enabled
There is. The parts other than the antenna are installed in the integrated base station 41.
And the antenna is the local base station 43₁, 43₂, ... to that
Each is installed.

In the road-vehicle communication system, the integrated base station 41 generates a data packet and a notification packet modulated by a predetermined wireless modulation method, and converts the wireless signal into an optical signal by the wireless optical conversion device. The wireless optical conversion device is configured to convert an optical signal from, for example, a laser diode into an optical signal directly or by an optical modulator. This optical signal is transmitted to the optical fibers 42 ₁ , 42 ₂ , ...
Through the ... one or more of the local base station 43 _1, 43 _2, ...
Sent to. In the local base stations 43 ₁ , 43 ₂ , ..., Optical optical conversion devices represented by photodiodes convert optical signals into signals in the radio frequency band, and the radio signals are transmitted from the roadside antenna to the terminal and notified to the terminal. Transmit the packet.

The terminal mounted on the vehicle 44 has an antenna for receiving the radio signal radiated from the roadside antenna, and a connecting portion for sending the radio signal received by the antenna to the corresponding mobile phone or broadcast receiver. I have it. Also,
In the uplink, the local base stations 43 ₁ , 43 ₂ , ... Receive the download or upload request packet, the data packet, and the recognition response packet modulated by the predetermined wireless modulation method from the terminal, and The optical fiber 42 ₁ , 42 ₂ , ... Is converted into an optical signal by the wireless optical converter having the same principle as the wireless optical converter described above.
・ Transmitting to the integrated base station 41 via. Integrated base station 41
In (1), an optical wireless conversion device having the same principle as the optical wireless conversion device described above converts the signal into a radio frequency band signal and receives a packet transmitted from the terminal.

It should be noted that the individual radio frequency or intermediate frequency modulated by the frequency conversion integrated distribution device provided in the integrated base station 41 such as a mobile phone or broadcasting is included in a certain specific frequency band, for example, a millimeter wave band. In addition, integrated conversion may be performed and a radio signal in the shared frequency band may be radiated from the roadside antenna. In this case, the terminal mounted on the vehicle 44 has an antenna having sensitivity in the shared frequency band and a frequency to be distributed by converting a radio signal received by the antenna into a radio signal of an individual radio frequency or an intermediate frequency. It is provided with a converter / distributor and a connection unit for sending individual radio frequency and intermediate frequency radio signals from the frequency converter / distributor to corresponding mobile phones and broadcast receivers.

The base station 1 shown in FIG. 1 is an integrated base station 41 and local base stations 43 ₁ and 4 in the system of FIG.
It corresponds to the whole 3 ₂ . The terminal 21 shown in FIG. 2 corresponds to the terminal mounted in the vehicle 44. In one embodiment, base station 1 to terminal 2
1 to the downlink and vice versa from terminal 21 to base station 1
Is configured to be able to simultaneously communicate with the uplink. For example, a modulation method in which carrier frequencies are different between both lines is used.

A frame structure according to an embodiment of the present invention will be described with reference to FIG. In FIG.
BS represents the base station 1 and T1 to Tn represent each of the n terminals. As shown in FIG. 4A, one downlink frame transmitted via the downlink is composed of one notification slot (shaded slot) and one or a plurality of, for example, 7 data slots. The division of continuous time into fixed intervals is called slotting, and each of the divisions is called a slot. A notification packet is inserted in the notification slot, and a data packet is inserted in the data slot. The notification packet and the data packet from the base station BS are respectively received by the terminals T1 to Tn. Note that FIG. 4A shows an example of the configuration of the downlink frame, and various modifications are possible. For example, the notification slot and the data slot may have different lengths, and the notification slot may be at the end of the frame.

As described above, in the notification packet, the usage status of each data slot in the downlink frame which is about to be transmitted, the information about the usage schedule of each data slot in the next downlink frame, and the uplink frame The information includes the usage status of each data slot, the usage schedule information of each data slot in the next upstream frame, and the reception status information at the base station for the upload packet transmitted by the terminal in the previous upstream frame.

FIG. 4B shows an example of the structure of the upstream frame. The upstream frame includes one or a plurality of, for example, five data slots, a download request slot in which a download request packet is placed, an upload request slot in which an upload request packet is placed, and an ACK slot. The ACK slot has a one-to-one correspondence with the seven data slots downloaded from the base station BS. Note that FIG. 4B is an example of the configuration of the upstream frame, and various modifications are possible. For example, the request slot may be located at the beginning of the frame, the ACK slot may be located at the beginning of the frame, and the reception status of the data packet received in the previous downlink frame may be returned by the ACK packet arranged in the ACK slot. Is also good.
Further, a configuration in which data slots and ACK slots are alternately located is possible.

At least one slot is required for each of the download request slot and the upload request slot. However, when the number of request slots is small, when each terminal transmits a request packet to the base station 1, there is a high possibility of collision. On the other hand, increasing the number of request slots reduces the number of data slots. Therefore, in the example of FIG. 4B, the number of download request slots is 7, and the number of upload request slots is 5. Furthermore, the number of download request packets or upload request slots may be adjustable or changeable. Furthermore, it is possible to insert the request slot in the data slot in a time division manner.

Although one packet is placed in one slot, two or more packets may be placed in one slot. As an example, one packet used in Ethernet (registered trademark) is transmitted to each data slot. In this case, one packet used in Ethernet (registered trademark) may be segmented and transmitted in each data slot. Further, in each notification slot, a broadcast packet used in Ethernet (registered trademark) is transmitted. Ethernet (registered trademark) IE
EE (Institute of Electrical and Electronics Enginee
rs) means 802.3 standard. There are standards such as 10BASE-T, 100BASE-T, and Gigabit Ethernet depending on the transmission medium and transmission speed used in this standard.

Explaining the relationship between the timing of the downlink frame and the timing of the uplink frame, when transmitting the download request packet and the upload request packet, the base station has a margin to generate the notification packet of the next frame by reflecting the request packet. is necessary. In addition, A having the information of the reception status of the data packet of the downlink frame
All CK packets need to be transmitted to the base station 1 by the time the upload starts in order to avoid collision with the upload of the next frame. Furthermore, it is necessary to start sending the upload data packet and the request packet after receiving the notification packet from the base station. The timing relationship shown in FIG. 4 satisfies these conditions.

When a download or upload request is issued to the terminal 21, the terminal 21 uses any download request slot or upload request slot of the next frame according to the content notified from the base station 1 to send a request packet. Is transmitted to the base station 1 via the uplink.

More specifically, the transmission of the request packet will be described. When the notification packet notifies the following case, the terminal does not transmit the request packet,
After a lapse of an arbitrary time, the same request packet transmission process is performed again.

In the first case, when a download request is made,
This is the case where all the data slots in the next downlink frame are scheduled to be used (that is, when there is no empty data slot). The second case is when an upload request is made to use all data slots in the next upstream frame (that is, when there is no empty data slot).

In addition, when a plurality of terminals transmit request packets in the same request slot, request packet collision occurs in the receiving device of the base station, and from which terminal the base station transmitted the request packet. If not identified, the base station cannot allocate a data slot to the terminal that sent the request packet, and generates and sends a notification packet with no data slot allocation to the terminal that sent the request packet. To do. In this case, the terminal that sent the request packet receives the notification packet and determines that the request packet has not been correctly received by the base station because the data slot is not allocated. Performs request packet transmission processing. When a collision occurs, if there is a power difference between the base station receiver and each terminal, the request packet from the terminal with the highest received power can reach the base station receiver. There is a nature.

FIG. 5 is a flowchart showing the flow of processing performed by the base station 1 in each frame. When the download request packet from the terminal arrives at the base station 1, the downlink frame data slot allocation process (step S1) is performed. When the upload request packet arrives at the base station 1, the uplink frame data slot allocation processing (step S2) is performed. Step S1
Details of each process of S2 and S2 will be described later. Note that unlike the example of FIG. 5, the uplink frame data slot allocation processing may be performed first, and then the downlink frame data slot allocation processing may be performed. Alternatively, these processes may be performed in parallel.

Then, in step S3, a notification packet is generated. The notification packet is generated from the usage status of the data slot of this frame and the next frame and the reception status of the upload packet received in the immediately preceding upstream frame. In step S4, the generated notification packet is transmitted.

In step S5, a data packet is transmitted to the terminal using each data slot of the downlink frame. As will be described later, the terminal 21 that has issued the download request receives the notification packet and the data packet transmitted from the base station 1, and transmits the reception status to the base station using the ACK slot.

Step S6 is a process of receiving the request packet, upload packet and ACK packet contained in each slot of the upstream frame. As will be described later, the terminal 21 that has made the upload request receives the notification packet transmitted from the base station 1 and transmits the data packet to the base station using the assigned data slot. When step S5 or S6 ends, the process returns to step S1 to process the next frame.

When the transmission to a certain terminal or the reception from a certain terminal is completed, the base station releases the data slot allocated to that terminal.

When a base station transmits a data packet to a terminal and receives a request packet from another terminal, one data slot is assigned to each terminal from the next frame, and all the remaining Empty data slot of
Assign to each terminal according to a certain rule. An example of the rule is shown below.

In the case of a download request, all empty data slots are assigned to the terminal having the smallest remaining number of data packets to be transmitted to each terminal. In the case of an upload request, all empty data slots are assigned to the terminal having the smallest number of remaining data packets received from each terminal. If there is still an empty data slot, the empty data slot is assigned to the terminal having the next fewest number of remaining data packets. This allocation process is performed until there are no available data slots or there are no terminals to allocate.

This data slot allocation rule will be described in more detail by taking download as an example. Similar rules apply for uploads. This allocation rule is a first rule that allocates all empty data slots to a terminal when a download request packet is not received from one or more other terminals while transmitting a data packet to the terminal. When a download request packet is received from one or more other terminals while transmitting a data packet, the request packet is transmitted in each frame after the frame after the frame in which the download request packet is received. One data slot is allocated to the terminal, the remaining empty data slot in each frame is allocated to the terminal having the fewest remaining number of data packets to be transmitted, and the empty data slot is still in each frame. If there is, the remaining free data stream will be Consists of a second rule for assigning the Tsu bets are those processing based on the second rule is made up or empty data slot is eliminated, or assigned terminal eliminated.

Several variations of the second rule are possible. A first modified example relating to the second rule is that, when a download request packet is received from one or more other terminals while transmitting a data packet to the terminal, a frame next to the frame that received the request packet is received. In each subsequent frame, one data slot is assigned to each terminal that has transmitted the request packet, and the remaining empty data slot in each frame is assigned to the terminal with the earliest arrival of the request packet. If there is still an empty data slot in each frame, the remaining empty data slots are assigned in the order of terminals with the earliest arrival of request packets.

A second modification of the second rule is that, when a download request packet is received from one or more other terminals while transmitting a data packet to the terminal, the frame of the received request packet In each frame after the next frame, the data slots in one frame are equally allocated to each terminal that transmitted the request packet.

A third modification of the second rule is that, when a download request packet is received from one or more other terminals while transmitting a data packet to the terminal, the frame of the frame in which the request packet is received is received. In each frame after the next frame, one data slot is assigned to each terminal that transmitted the request packet, and if there is still an empty data slot in each frame, the priority of the data packet to be transmitted. The remaining free data slot is assigned to the terminal with the highest.

FIG. 6 shows details of an example of the downlink frame data slot allocation processing (step S1) performed when the download request packet from the terminal arrives at the base station. In the first step S11, it is checked whether or not there is a data packet to be transmitted to the terminal in the downlink frame which is going to allocate the data slot. Usually, the data slot in the next downlink frame when the download request packet arrives is allocated. If there is no data packet, the slot allocation is unnecessary and the allocation processing ends, and the process moves to the upstream frame data slot allocation processing S2.

When it is determined in step S11 that there is a data packet to be transmitted to the terminal, step S1
In step 2, one data slot is assigned to one or more terminals that transmitted the request packet (step S1
2). In the next step S13, it is checked whether there are any data packets left to be transmitted to the terminal. If no data packet remains, the data slot allocation processing ends. If there are data packets left,
In step S14, it is determined whether or not there is an empty data slot in the downlink frame.

When it is determined in step S14 that there is no free data slot, the process proceeds to step S16. Step S16 is a process of determining the presence / absence of a terminal that continuously transmits a data packet in the next frame.
If it is determined in step S14 that there is a vacant data slot, a vacant data slot is allocated to the terminal in which the data packet remains before step S16 (step S15).

In step S16, if it is determined that there is no terminal that transmits the data packet even in the next frame, the data slot allocation process ends. If not, that is, if all the data requested by the terminal in this frame cannot be transmitted, step S17
At, the process of securing (scheduling to use) the required number of data slots in the next downlink frame is performed.

FIG. 7 shows details of an example of the uplink frame data slot allocation processing (step S2) performed when the upload request packet from the terminal arrives at the base station. Usually, the data slot in the next upstream frame when the upload request packet arrives is allocated. The uplink frame data slot allocation processing is the same as the downlink frame allocation processing described above. In the first step S21, it is checked whether or not there is a data packet received from the terminal in the upstream frame which is going to allocate the data slot. If there is no data packet, slot allocation is unnecessary, so the allocation processing ends, and the processing moves to the notification packet generation processing S3.

When it is determined in step S21 that there is a data packet to be received from the terminal, step S2
In step 2, one data slot is assigned to one or more terminals that transmitted the request packet (step S2
2). In the next step S23, it is checked whether or not there are any remaining data packets to be received from the terminal. If no data packet remains, the data slot allocation processing ends. If there are data packets left,
In step S24, it is determined whether or not there is a free data slot in the upstream frame.

If it is determined in step S24 that there is no empty data slot, the process proceeds to step S26. Step S26 is a process for determining the presence / absence of a terminal that continuously transmits a data packet in the next frame.
If it is determined in step S24 that there is a vacant data slot, a vacant data slot is allocated to the terminal with the data packet remaining before step S26 (step S25).

When it is determined in step S26 that there is no terminal that transmits the data packet in the next frame, the data slot allocation process ends. If not, that is, if the terminal cannot transmit all the data in this frame, in step S27,
Processing is performed to secure the required number of data slots in the next upstream frame (to be used).

In one embodiment, when the terminal 21 receives a notification from the base station 1 that the next frame has a vacancy, the terminal 21 having the request packet receives any notification until the next notification packet. Send a download or upload request packet using a free download or upload request slot. 8 and 9 are flowcharts showing in more detail an example of the processing flow of the terminal 21. FIG. 8 and FIG. 9 are a series of flowcharts divided into two parts in view of the restriction of the drawing space. The request packet generation unit 23 in FIG. 2 performs a request packet generation process.

The first step S31 shows a standby state. In the next step S32, it is determined whether or not a request has occurred. When it is determined that the request does not occur, the process returns to the standby state (step S31). In step S32,
When it is determined that the request has been generated, a request packet (download or upload request packet) is generated in step S33.

A step S34 shows a waiting state of an arbitrary length of time, and after the waiting state, a notification packet is received from the base station 1 in a step S35. In step S36, it is determined whether the request generated at the terminal is a download request. In the case of a download request, whether or not there is an empty data slot in the next downlink frame is determined in step S37 based on the content of the notification packet. If it is not a download request, that is, if it is an upload request, whether or not there is an empty data slot in the next upstream frame is determined in step S38 based on the content of the notification packet.

When it is determined in steps S37 and S38 that there is no empty data slot, the process returns to the waiting step S34 and waits without transmitting the request packet.

The case where there is no empty data slot will be described more specifically. For example, when one frame is composed of 7 data slots, it is assumed that each of the 7 data slots in the frame to be transmitted is allocated to 7 terminals. Then, it is assumed that there are a plurality of data packets to be transmitted to the seven terminals and that all data packets cannot be transmitted in this frame. In this case, since the data packet is continuously transmitted to the seven terminals in the next frame, each data slot in the next frame is assigned to each of the seven terminals. As a result, there are no empty data slots in the next frame. In this way, when data slots and terminals are assigned one-to-one and a large amount of data is transmitted to each terminal, there occurs a situation where there is no empty data slot in this frame and the next frame.

When it is determined in steps S37 and S38 that there is an empty data slot, a request slot for transmitting a request packet is arbitrarily determined in step S39. Then, in step S40, the request packet is transmitted. The download request packet is transmitted using the download request slot,
The upload request packet is transmitted using the upload request slot.

The next notification packet is received in step S41. In step S42, it is determined whether the transmitted request packet has been received, based on the information of the received notification packet. That is, it can be determined that the request packet has been received when the notification slot includes information in which the data slot is assigned to itself. If it is determined in step S42 that the request packet has not been received due to a collision or the like, the process returns to step S34 (standby). If the standby state is unnecessary, as shown by the broken line, step S36 (step of determining whether the request is a download request).
You may return to.

When it is determined in step S42 that the request packet has been received by the base station, as shown in FIG. 9, it is checked in step S43 whether the request is a download request. In the case of a download request, the terminal receives the data packet transmitted from the base station (step S44). In the next step S45, it is determined whether or not the reception of the data packet in this frame is completed. If not completed, the process returns to step S44, and the data packet is continuously received. When the processing is completed, in step S46, an ACK packet including information indicating the reception status is transmitted using the ACK slot.

In step S47 following step S46, it is determined whether reception of all data packets has been completed. If it is determined that it is not finished, step S
At 48, the notification packet is received, and then the process proceeds to step S44 (data packet reception). When reception of all data packets is completed, step S4
If determined in step 7, step S31 (see FIG. 8)
The process returns to.

If it is determined in step S43 that it is not a download request, that is, an upload request, a data packet is transmitted using the data slot of the upstream frame in step S49.
In step S50, it is determined whether the transmission of the data packet in this frame is completed. If not completed, the process returns to step S49, and the data packet is continuously transmitted.

In step S51 following step S50, it is determined whether or not the transmission of all data packets has been completed. If it is determined that it is not finished, step S
In 52, the notification packet is received, and the process proceeds to step S49 (data packet transmission). When transmission of all data packets is completed, step S5
If determined in step 1, step S31 (see FIG. 8)
The process returns to. It should be noted that when the reception of all data from a certain terminal is completed, the data slot assigned to that terminal is released.

An example of the communication operation of the embodiment of the present invention described above will be conceptually described with reference to the timing charts of FIGS. 10, 11, 12 and 13. FIGS. 10 to 13 show timing charts continuous in the time axis direction, which are divided into approximately one frame due to the restriction of the drawing space. Also, FIG. 10A and FIG.
The timing charts of A, FIG. 12A, and FIG. 13A are
A packet transmission operation using a downlink from the base station 1 to the terminal 21 is shown. The timing charts of FIG. 10B, FIG. 11B, FIG. 12B, and FIG. 13B show the packet transmission operation using the uplink from the terminal 21 to the base station 1.

The timing chart shows the terminal 21 as
For example, this is an example in which there are five terminals. BS is base station 1
, And T1 to T5 are reference codes of each terminal. The reference symbol of info is a notification packet transmitted from the base station BS to all terminals at the same time, and the terminal T1.
7 shows the notification packets received by T5. In the following example, one downlink frame includes 7 data slots,
One upstream frame includes 5 data slots.
Further, it is assumed that the amount of data downloaded or uploaded is the amount transmitted using 6 data slots. However, the data amounts do not have to be equal, and may be the amount (fixed or variable) that can be transmitted using any data slot.

It is assumed that the terminals T1 and T3 issue a download request and the terminal T2 issues an upload request at a timing (not shown) before the upstream frame shown in FIG. 10B. That is, in the processing of the terminal shown in FIG.
The request is generated in 2, the request packet is generated in the next step S33, and the standby state is set in step S34.

The terminals T1 to T5 receive the notification packet 51 at the beginning of the downlink frame shown in FIG. 10A. When the terminals T1 and T3 detect from the content of the notification packet that there is an empty data slot in the next downlink frame,
As shown in 0B, the download request packets 52 and 53 are transmitted using the first and third download request slots. When the terminal T2 detects from the content of the notification packet that there is a vacant data slot in the next upstream frame, the terminal T2 transmits the upload request packet 54 using the second upload request slot as shown in FIG. 10B. .

Request packets from these terminals T1, T2, T3 are received by the base station BS. It is determined from the contents of the notification packet of the next frame whether the request packet has been received by the base station. Also, the terminal can know the data slot allocation made by the base station from the notification packet.

FIG. 11 is a timing chart of the next frame. In the downlink frame shown in FIG. 11A,
The base station receiving the download request packets from the terminals T1 and T3 allocates the first and third data slots to the terminals T1 and T3, respectively. The number of remaining data packets depends on the terminals T1 and T3.
There are five equally between. In this example, as shown in FIG. 11A, five data slots are assigned to the terminal T1. In the reference numerals attached to the data packets such as “1-1” and “1-2”, the leading numeral is the terminal (in this example, T
1), and the next number indicates the number of the data packet.
For example, data packets to be downloaded to the terminal T1 are "1-1" to "1-6". As shown in FIG. 11A, X is attached to the data packet “1-5” arranged in the sixth data slot because the terminal T1 cannot normally receive this data packet. It means that. Here, the first data slot assigned to each terminal is
It corresponds to the slot that sent the request packet. However, such a correspondence relationship is not essential, and the data slots may be sequentially assigned from the terminal 1, for example.
In this example, the first to sixth data slots are assigned to the terminal T1, and the seventh data slot is assigned to the terminal T3.

In the upstream frame shown in FIG. 11B,
The terminal T2 uses all the data slots to transmit the data packets "2-1" to "2-5" to the base station BS. As shown in FIG. 11B, X is attached to the data packet “2-5” arranged in the fifth data slot, because the base station BS could not normally receive this data packet. Is represented.

As shown in FIG. 11B, the terminal T1 is connected to the third
The ACK packet indicating that the packet in the data slot other than the sixth and sixth data slots is normally received is transmitted to the base station BS, and the packet in the sixth data slot is not normally received. The acknowledge response packet NACK packet shown (shown in black in FIG. 11B) is transmitted to the base station BS. Terminal T3
Transmits to the base station BS an ACK packet indicating that the packet of the third data slot has been normally received. The base station BS receives the ACK packet and NA
Among the data packets transmitted from the CK packet to the terminal T1, "1-5" indicates that the terminal T1 could not be normally received. The base station BS retransmits the data packet “1-5” after a predetermined time.

Among the transmitted data packets, the terminal T2 knows that the data packet "2-5" was not correctly received by the base station from the contents of the notification packet of the next frame. The terminal T2 receives the data packet “2-
5 "is retransmitted after a predetermined time. Further, as shown in FIG. 11B, the terminal T4 transmits the upload request packet 55, the terminal T5 transmits the download request packet 56, and these request packets 55 and 56 are transmitted to the base station B.
Received by S. The base station BS allocates the data slot of the next frame based on the remaining data packet that has not been transmitted or received and the new download request and upload request, and a notification packet including allocation information is created. .

In the downlink frame shown in FIG. 12A, the terminal T
Of T3 and T5, a vacant data slot (first, second, third, fourth and sixth data slot) is assigned to the terminal T3 having a smaller remaining number of data packets to be downloaded. The remaining data slots, the fifth and seventh data slots, are assigned to the terminal T5. The terminal T3 uses the remaining data packet "3-2".
~ "3-6" is received. The terminal T5 receives the data packets "5-1" and "5-2".

In the upstream frame shown in FIG. 12B, the terminal T
Of T2 and T4, a vacant data slot (first and second data slot) is assigned to the terminal T2 having a smaller number of remaining data packets to be uploaded. Data packet “2-5” that could not be uploaded in the previous frame in the first data slot
Is retransmitted, and the data packet “2-6” is transmitted in the second data slot. The remaining data slots, the third, fourth and fifth data slots, are assigned to the terminal T4. The terminal T4 sends the data packet "4-
1 ”,“ 4-2 ”and“ 4-3 ”are transmitted.

Further, in the upstream frame shown in FIG. 12B, the terminal T3 transmits an ACK packet indicating that the five data packets have been normally received, to the base station BS, and the terminal T5 normally transmits the two data packets. An ACK packet indicating reception is transmitted to the base station BS.

In the downlink frame shown in FIG. 13A, the first data slot is assigned to the terminal T1 and the data packet "1-5" is retransmitted via this data slot. The remaining empty data slot is assigned to the terminal T5. That is, data packets "5-3" -using the second, third, fourth and fifth data slots.
"5-6" is transmitted to the terminal T5.

In the upstream frame shown in FIG. 13B, the first,
The second and fourth data slots are assigned to the terminal T4, and the data packets "4-4", "4-5" and "4-6" are transmitted via these data slots. Further, the terminal T1 transmits an ACK packet indicating that the data packet "1-5" has been received, and the terminal T5
Are data packets “5-3”, “5-4”, “5-5”
And an ACK packet indicating that "5-6" has been received.

The present invention is not limited to the above-described embodiment of the present invention and the like, and various modifications and applications can be made without departing from the gist of the present invention. For example, the present invention can be applied not only to road-to-vehicle communication but also to other wireless data communication such as wireless LAN. Further, two or more notification slots for notification packets may be provided in one frame. Further, the notification packet may include information on the usage status of the data slot of the later frame in addition to the frame and the next frame.

[0084]

According to the present invention, it is possible to allocate a plurality of data slots of an uplink frame and a plurality of data slots of a downlink frame to a terminal, so that one data slot in one frame can be assigned to one terminal. Throughput can be increased in both the upstream and downstream directions compared to the allocation method. The present invention is suitable for transmitting (downloading and uploading) data that occurs in bursts, such as multimedia data.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration example of a base station according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration example of a terminal in an embodiment of the present invention.

FIG. 3 is a schematic diagram used for explaining a road-vehicle communication system to which the present invention can be applied.

FIG. 4 is a schematic diagram showing respective configurations of a downlink frame and an uplink frame in the embodiment of the present invention.

FIG. 5 is a flowchart for explaining a processing operation of the base station.

FIG. 6 is a flowchart for explaining a data slot allocation processing operation of a downlink frame of a base station.

FIG. 7 is a flowchart for explaining a data slot allocation processing operation of an uplink frame of a base station.

FIG. 8 is a flowchart for explaining a processing operation of the terminal.

FIG. 9 is a flowchart illustrating a processing operation of a terminal.

FIG. 10 is a timing chart for explaining the communication operation of the embodiment of the present invention.

FIG. 11 is a timing chart for explaining the communication operation of the embodiment of the present invention.

FIG. 12 is a timing chart for explaining the communication operation of the embodiment of the present invention.

FIG. 13 is a timing chart for explaining the communication operation of the embodiment of the present invention.

[Explanation of symbols]

1 ... Base station, 3 ... Data packet generator, 4 ...
..Notification packet generation unit, 6 ... Wireless device, 10 ...
-Reception packet determination unit, 21 ... Terminal, 23 ... Request packet generation unit, 24 ... Data packet generation unit,
25 ... ACK packet generation unit, 27 ... Wireless device, 31 ... Received packet determination unit, 41 ... Integrated base station, 43 ₁ , 43 ₂ , 43 ₃ ... Local base station, 44
···vehicle

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Masayuki Fujise             4-2-1 Kanaikitamachi, Koganei City, Tokyo Independent             Communications Research Institute F-term (reference) 5K034 AA02 EE03 EE11                 5K067 AA13 BB12 BB21 BB43 CC08                       EE02 EE10 EE13 EE24 EE71

Claims (8)

[Claims] 1. A downlink from a base station to a terminal and an uplink from a terminal to a base station can be simultaneously communicated, and a downlink frame transmitted through the downlink includes one or more notification slots and one or more data slots. In the communication method in the communication system, wherein the uplink frame transmitted through the uplink comprises one or more data slots, one or more request slots and a recognition response slot, the download request placed in the request slot. In response to the packet, performing a process of allocating, to the terminal, one or more data slots that are included in a downlink frame subsequent to the downlink frame that has received the download request packet and are vacant, The upload request packet placed in the request slot In response to the upload request packet, a process of allocating, to the terminal, one or more data slots that are included in an upstream frame subsequent to the upstream frame that received the upload request packet and are vacant, Information on the usage status of each data slot of the downlink frame and the above uplink frame, the usage status of each data slot of the next downlink frame and the next uplink frame, and the reception status for the upload packet transmitted by the terminal in the previous uplink frame Generating a notification packet having the following: transmitting the notification packet in the notification slot via the downlink and transmitting the data packet in the data slot; and, when transmission to the terminal is completed, The data slot assigned to the terminal The step of releasing, the step of receiving the data packet, the request packet, and the recognition response packet included in each of the data slot, the request slot, and the recognition response slot via the uplink, and the reception from the terminal is completed. In this case, the step of releasing the data slot assigned to the terminal is performed. 2. The downlink from the base station to the terminal and the uplink from the terminal to the base station can be simultaneously communicated, and the downlink frame transmitted through the downlink includes one or more notification slots and one or more data slots. In the communication method in the communication system, wherein the uplink frame transmitted through the uplink is composed of one or more data slots, one or more request slots and a recognition response slot, Information about the usage status of each data slot of the frame and the above-mentioned upstream frame, the usage status of each data slot of the next downlink frame and the next upstream frame, and the reception status of the upload packet transmitted by the terminal in the previous upstream frame. Receiving a notification packet having The step of transmitting a request packet through the request slot of the uplink, and when the request packet is a download request, the data packet from the base station is received through the data slot of the downlink and received. A communication method in which a recognition response packet indicating the situation is transmitted via the recognition response slot, and when the request packet is an upload request, a data packet is transmitted to the base station via the data slot of the uplink. . 3. The communication method according to claim 1, wherein the request slot includes a download request packet slot and an upload request packet slot. 4. The request packet according to claim 2, wherein when the request packet is a download request, the request packet is transmitted when the notification packet indicates that there is an empty data slot in the next downlink frame, A communication method, wherein when the request packet is an upload request, the request packet is transmitted when the notification packet indicates that there is an empty data slot in the next upstream frame. 5. The downlink from the base station to the terminal and the uplink from the terminal to the base station can be simultaneously communicated, and the downlink frame transmitted through the downlink includes one or more notification slots and one or more data slots. In a base station in a communication system configured according to the above, the uplink frame transmitted through the uplink includes one or more data slots, one or more request slots, and a recognition response slot, and a download request placed in the request slot. A means for responding to the packet, allocating to the terminal one or more data slots that are included in a downlink frame subsequent to the downlink frame that received the download request packet and are vacant; It responds to the upload request packet placed in the request slot. In response, means for performing a process of allocating, to the terminal, one or more empty data slots that are included in the upstream frames following the upstream frame that received the upload request packet, and the downstream frame. And the usage status of each data slot of the above-mentioned upstream frame, the usage status of each data slot of the next downstream frame and the next upstream frame, and the reception status for the upload packet transmitted by the terminal in the previous upstream frame. A means for generating a notification packet and transmitting the notification packet in the notification slot via the downlink, transmitting the data packet in the data slot, and when transmission to the terminal is completed,
Means for releasing the data slot assigned to the terminal, and receiving the data packet, the request packet, and the recognition response packet included in each of the data slot, the request slot, and the recognition response slot via the uplink, A base station comprising means for releasing the data slot allocated to the terminal when reception from the terminal is completed. 6. The downlink from the base station to the terminal and the uplink from the terminal to the base station can be simultaneously communicated, and the downlink frame transmitted through the downlink includes one or more notification slots and one or more data slots. In a terminal in a communication system, in which an uplink frame transmitted through the uplink is composed of one or more data slots, one or more request slots and a recognition response slot, the downlink frame is allocated to the notification slot. And the usage status of each data slot of the above-mentioned upstream frame, the usage status of each data slot of the next downstream frame and the next upstream frame, and the reception status for the upload packet transmitted by the terminal in the previous upstream frame. Means for receiving notification packets and requests Means for transmitting a packet through the request slot of the uplink, and when the request packet is a download request, a data packet from the base station is received through the data slot of the downlink and received. A terminal adapted to transmit a recognition response packet indicating the situation through the recognition response slot, and when the request packet is an upload request, transmit a data packet to the base station through the data slot of the uplink. 7. The downlink from the base station to the terminal and the uplink from the terminal to the base station can be simultaneously communicated, and the downlink frame transmitted through the downlink includes one or more notification slots and one or more data slots. And the uplink frame transmitted through the uplink comprises one or more data slots, one or more request slots and a recognition response slot, the base station is arranged in the request slot. A means for responding to the download request packet, allocating to the terminal one or more data slots that are included in the downlink frames subsequent to the downlink frame that received the download request packet and are empty. , In the upload request packet placed in the above request slot In response, means for performing a process of allocating, to the terminal, one or more empty data slots that are included in the upstream frames following the upstream frame that received the upload request packet, and the downstream frame. And the usage status of each data slot of the above-mentioned upstream frame, the usage status of each data slot of the next downstream frame and the next upstream frame, and the reception status for the upload packet transmitted by the terminal in the previous upstream frame. A means for generating a notification packet and transmitting the notification packet in the notification slot via the downlink, transmitting the data packet in the data slot, and when transmission to the terminal is completed,
Means for releasing the data slot assigned to the terminal, and receiving the data packet, the request packet, and the recognition response packet included in each of the data slot, the request slot, and the recognition response slot via the uplink, When reception from the terminal is completed, the terminal comprises means for releasing the data slot allocated to the terminal, the terminal receiving the notification packet, and the request packet for transmitting the request packet to the uplink request slot. When the request packet is a download request, the data packet from the base station is received through the data slot of the downlink, and the recognition response packet indicating the reception status is recognized. If you send it via the response slot and the above request packet is an upload request, , A data packet is transmitted to the base station via the data slot of the uplink, the base station has an integrated base station, and the downlink is modulated by the integrated base station by a wireless modulation method. The generated data packet and the notification packet are generated, the generated data packet and the notification packet is radiated to the terminal, transmitted from the terminal, the request packet modulated by a wireless modulation method, A communication system, wherein the recognition response packet and the data packet are transmitted to the integrated base station, and optical-wireless converted in the integrated base station. 8. The wireless communication system according to claim 7, wherein the base station is connected to the integrated base station via an optical communication path, and further has one or more local base stations each provided with an antenna. The data packet and the notification packet are converted into an optical signal, the optical signal is transmitted to the local base station through the optical communication path, and the local base station performs optical wireless conversion, and the local base station. Of the request packet, the recognition response packet and the data packet, which are radiated from the antenna of the terminal and transmitted from the terminal, which are modulated by a wireless modulation method, are received by the antenna of the local base station, The received signal is subjected to wireless optical conversion by the local base station, the optical signal is transmitted from the local base station to the integrated base station via the optical communication path, the integrated base A communication system characterized by being optically / wirelessly converted at a station.