JP2009124229A - Radio transmission system and packet transmission terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent loss of data packets by rationalizing the transmission amount of the data packets. <P>SOLUTION: A radio transmission system includes: a data packet transmission part 11 which transmits data packets to a packet reception terminal 2 by using a satellite line; an own station data packet reception part 12 which receives data packets transmitted from the data packet transmission part 11 and turned by a satellite; and a line band calculation part 13 which calculates an available band of a radio line from the reception quality of data packets received by the own station data packet reception part 12. A data transmission amount control part 18 controls the transmission amount of data packets transmitted from the data packet transmission part 11, in accordance with the available band calculated by the line band calculation part 13. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wireless transmission system in which a packet transmitting terminal transmits a data packet to a packet receiving terminal using a wireless line, and a packet transmitting terminal that transmits a data packet to the packet receiving terminal using a wireless line. is there.

In recent disaster / defense monitoring systems and the like, there is a strong need to monitor aerial images from aircraft and helicopters with a base station, and wireless infrastructure such as satellite links is used for video transmission.
For example, in a wireless transmission system using a satellite line, a band (transmission throughput) that can be actually received may be reduced due to radio wave attenuation due to rain or the like, or due to aircraft speed, altitude, and attitude fluctuations.
As a method for solving this band reduction, there is a method for controlling the transmission power of a signal on the transmission side.
For example, Patent Documents 1 and 2 below disclose a method of controlling transmission power based on a comparison result between the signal level of a received beacon signal or pilot signal and a reference level.

Also, in a cellular radio transmission system, when a mobile device hands over a plurality of base station areas, it controls transmission On / Off from each base station and selects an access point having the best signal quality. In order to make the determination, the mobile station measures the channel quality using the pilot signal transmitted from the base station (see, for example, Patent Documents 3, 4, and 5).
Further, as a means for estimating the channel quality, there is a technique for analyzing packet loss and jitter on the receiving side, feeding back the analysis result to the transmitting side, and controlling the transmission band (see, for example, Patent Document 6). .

JP-A-62-133831 JP-A-01-170227 Japanese Patent Application Laid-Open No. 11-069416 Special table 2003-529971 gazette Japanese Patent Laid-Open No. 05-145457 JP 2001-230809 A

Since the conventional wireless transmission system is configured as described above, when the transmitting side is an aircraft with a large attitude fluctuation, the angle of the antenna is not fixed. Therefore, in the method for controlling the transmission power, the transmission power is amplified. There are cases where it is difficult to maintain the current line bandwidth, and there is a problem that data packets may be lost.
Also, in the method of analyzing the reception status of data transmitted from the transmission side and feeding back the analysis result to the transmission side, it takes time for the transmission side to acquire the latest analysis result due to the transmission delay of the line. In such a case, or when information to be fed back from the receiving side is missing and cannot be delivered to the transmitting side, there is a problem in that it is impossible to predict the line bandwidth accurately and in real time, leading to missing data packets.

  The present invention has been made to solve the above-described problems, and aims to obtain a wireless transmission system and a packet transmission terminal capable of optimizing the transmission amount of data packets and preventing loss of data packets. Objective.

  In the wireless transmission system according to the present invention, a packet transmitting terminal transmits a data packet to a packet receiving terminal using a wireless line, and the packet is transmitted from the data packet transmitting means and then folded back on the wireless line. A local data packet receiving means for receiving the received data packet; and a line bandwidth calculating means for calculating a usable bandwidth of the wireless line from the reception quality of the data packet received by the local data packet receiving means. The control means controls the transmission amount of the data packet transmitted from the data packet transmission means in accordance with the usable bandwidth calculated by the line bandwidth calculation means.

  According to the present invention, the packet transmitting terminal transmits a data packet to the packet receiving terminal using a wireless line, and the data packet transmitted from the data packet transmitting means and then returned by the wireless line A local data packet receiving means for receiving the data and a line bandwidth calculating means for calculating a usable bandwidth of the wireless line from the reception quality of the data packet received by the local data packet receiving means, Since the transmission amount of the data packet transmitted from the data packet transmission unit is controlled according to the available band calculated by the line bandwidth calculation unit, the transmission amount of the data packet can be optimized. As a result, it is possible to prevent data packets from being lost.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a radio transmission system according to Embodiment 1 of the present invention. In the figure, a packet transmitting terminal 1 is connected to a packet receiving terminal 2 via a network 3 consisting of a satellite line as a radio line, for example. It is connected.
Note that the packet transmission terminal 1 and the packet reception terminal 2 correspond to, for example, a portable information terminal such as a mobile phone, a wireless communication device mounted on an aircraft, or the like.

The data packet transmission unit 11 is a network interface device including, for example, a radio device and an antenna, and transmits a data packet to the packet receiving terminal 2 using a satellite line under the instruction of the data transmission amount control unit 18. Perform the process. The data packet transmission unit 11 constitutes a data packet transmission unit.
The local station data packet receiving unit 12 is a network interface device composed of, for example, a radio or an antenna, and performs a process of receiving a data packet that is transmitted from the data packet transmitting unit 11 and then returned by the satellite. . The own station data packet receiving unit 12 constitutes own station data packet receiving means.

The line bandwidth calculation unit 13 is composed of, for example, a semiconductor integrated circuit board on which an MPU, a memory, and the like are mounted, and the satellite line can be used from the reception quality of the data packet received by the local data packet reception unit 12. A process for calculating the bandwidth is performed. The line bandwidth calculation unit 13 constitutes line bandwidth calculation means.
The reception quality analysis unit 14 of the line bandwidth calculation unit 13 performs a process of analyzing the reception quality of the data packet received by the local station data packet reception unit 12.
The database 15 of the line bandwidth calculation unit 13 is a memory that manages the correspondence between the actual bandwidth of the wireless line and the reception quality.
The correspondence relationship managed in the database 15 is obtained by sampling and recording an actual band corresponding to past reception quality.

The line band determining unit 16 of the line band calculating unit 13 refers to the correspondence relationship managed in the database 15 and identifies the actual band of the satellite line corresponding to the reception quality analyzed by the reception quality analyzing unit 14. A process of determining the band as an available band of the satellite line is performed.
The line bandwidth correcting unit 17 of the line bandwidth calculating unit 13 corrects the available bandwidth of the satellite line determined this time according to the history of the available bandwidth of the satellite line previously determined by the line band determining unit 16. To implement.

The data transmission amount control unit 18 is composed of, for example, a semiconductor integrated circuit board on which an MPU is mounted, and the available bandwidth of the satellite channel determined by the channel bandwidth determination unit 16 of the channel bandwidth calculation unit 13 or A process for controlling the transmission amount of the data packet transmitted from the data packet transmission unit 11 according to the usable bandwidth of the satellite channel corrected by the channel bandwidth correction unit 17 is performed. The data transmission amount control unit 18 constitutes transmission amount control means.
The data packet receiving unit 21 of the packet receiving terminal 2 is a network interface device that receives the data packet transmitted from the data packet transmitting unit 11 of the packet transmitting terminal 1.
FIG. 2 is a flowchart showing the processing contents of the wireless transmission system according to Embodiment 1 of the present invention.

Next, the operation will be described.
First, the data packet transmitting unit 11 of the packet transmitting terminal 1 transmits a data packet to the packet receiving terminal 2 using an IP multicast address using a satellite line (step ST1).
The data packet receiving unit 21 of the packet receiving terminal 2 receives the data packet transmitted from the packet transmitting terminal 1 by participating in the same multicast address (also referred to as a multicast group) as the IP multicast address (step ST21, ST22).
The local data packet receiving unit 12 of the packet transmitting terminal 1 also receives the data packet that is transmitted from the data packet transmitting unit 11 and then returned by the satellite by participating in the same multicast address as the IP multicast address. (Step ST2).

When the local station data packet receiver 12 receives the data packet transmitted from the data packet transmitter 11 via the satellite line, the line bandwidth calculator 13 of the packet transmission terminal 1 calculates the reception quality of the data packet, The available bandwidth of the satellite line is calculated from the received quality.
The processing contents of the line bandwidth calculation unit 13 will be specifically described below.

When the local data packet receiving unit 12 receives the data packet, the reception quality analyzing unit 14 of the line bandwidth calculating unit 13 calculates a reception rate RR _i that is an index of the reception quality of the data packet (step ST3).
Since the calculation content of the reception rate RR _i in the reception quality analysis unit 14 is a known technique, detailed description thereof is omitted.

When the reception quality analysis unit 14 calculates the reception rate RR _i , the line bandwidth determination unit 16 of the line bandwidth calculation unit 13 refers to the correspondence managed in the database 15 and corresponds to the reception rate RR _i of the data packet. The actual bandwidth of the satellite link to be identified is specified, and the actual bandwidth is determined as the usable bandwidth SR _i of the satellite link.
In the database 15, for example, when the correspondence is managed as shown below, for example, if they match the reception rate RR _i data packet and reception rate R3, satellite link corresponding to the received rate RR _i of the data packets Is determined to be S3, and the usable bandwidth SR _i of the satellite line is determined to be S3.
Alternatively, if the reception rate RR _i of the data packet is between the reception rate R2 and the reception rate R3, and the reception rate RR _i is closer to the reception rate R2 than the reception rate R3, it corresponds to the reception rate RR _i of the data packet. The actual bandwidth of the satellite line is specified as S2, and the available bandwidth SR _i of the satellite line is determined as S2.

Correspondence relationship managed in the database 15 Reception rate Actual bandwidth of the satellite line R1 → S1
R2 → S2
R3 → S3
R4 → S4
:
:
RN → SN

In this example, the line bandwidth determination unit 16 specifies the actual bandwidth of the satellite line corresponding to the reception rate RR _i of the data packet and determines the actual bandwidth as the usable bandwidth SR _i of the satellite line. The packet reception rate RR _i may be determined as the usable bandwidth SR _i of the satellite line (step ST4).
In the first embodiment, the usable bandwidth SR _i of the satellite line determined by the line band determining unit 16 is output to the line band correcting unit 17, but without being output to the line band correcting unit 17, You may make it output to the data transmission amount control part 18. FIG.

When the line bandwidth correction unit 17 of the line bandwidth calculation unit 13 receives the usable bandwidth SR _i of the satellite line from the line bandwidth determination unit 16, this time according to the history of the available bandwidth of the satellite line determined in the past. The available band SR _i of the determined satellite link is corrected.
That is, the line band correction unit 17 stores the line band SR _i determined this time by the line band determination unit 16 as a history (step ST5), and the line band SR _i currently determined by the line band determination unit 16 and the previous time. A difference D _i (= SR _i−1 −SR _i ) from the determined line bandwidth SR _i−1 is calculated (step ST6).

Here, the greater the difference D _{i, the} worse the line quality, and the difference history (... D _i−3 , D _i−2 , D _i−1 , D _i ) becomes larger. It can be assumed that the line quality is getting worse.
On the other hand, if the difference history (... D _i-3 , D _i-2 , D _i-1 , D _i ) has become smaller (close to 0), it is assumed that the line quality has recovered. can do.

Next, the line bandwidth correction unit 17 calculates a line quality evaluation value W from the difference histories D _i-2 , D _i-1 , D _i and the currently determined line bandwidth SR _i as shown below. Then, the evaluation value W is compared with a predetermined threshold value α (step ST8).
W = ((D _i + D _i-1 + D _i-2 ) / 3) / SR _i
If the evaluation value W is greater than the threshold value α, the line bandwidth correction unit 17 assumes that the line quality has deteriorated, and the line bandwidth SR _i determined this time becomes a somewhat smaller value as shown below. (Step ST9).
SR _i = SR _i × (1-W)
On the other hand, if the evaluation value W is equal to or less than the threshold value α, it is assumed that the line quality has been recovered, and correction is made so that the line band SR _i determined this time becomes a somewhat large value as shown below ( Step ST10).
SR _i = SR _i × β where β> 1.0

When the data transmission amount control unit 18 of the packet transmission terminal 1 receives the usable bandwidth SR _i of the satellite channel from the channel bandwidth correction unit 17 (or the channel bandwidth determination unit 16) of the channel bandwidth calculation unit 13, the channel bandwidth The transmission amount of the data packet transmitted from the data packet transmission unit 11 is controlled according to SR _i .
That is, the data transmission amount control unit 18 adjusts the number, interval, and size of the transmission target packets so that the transmission rate of the data packets transmitted from the data packet transmission unit 11 matches the line bandwidth SR _i (step). ST11).
For example, when the packet transmission terminal 1 transmits live video captured by a camera, the data transmission amount control unit 18 functions as a video or audio encoder, and the line bandwidth SR _i output from the line bandwidth correction unit 17. Is set to the target encoding rate of the encoder to perform encoding.
Thereafter, the processes of steps ST1 to ST12 are repeatedly performed until the data transmission is completed (step ST13).

  As is apparent from the above, according to the first embodiment, the data packet transmitting unit 11 that transmits the data packet to the packet receiving terminal 2 using the satellite line and the data packet transmitting unit 11 transmit the data packet. A local station data packet receiving unit 12 that receives a data packet returned by a satellite, and a line band calculating unit that calculates a usable bandwidth of the radio channel from the reception quality of the data packet received by the local station data packet receiving unit 12 13, and the data transmission amount control unit 18 is configured to control the transmission amount of the data packet transmitted from the data packet transmission unit 11 in accordance with the available bandwidth calculated by the line bandwidth calculation unit 13. This makes it possible to optimize the transmission amount of data packets and, as a result, prevent data packets from being lost. Achieve the kill effect.

  Further, according to the first embodiment, the line bandwidth correction unit 17 can use the satellite line determined this time according to the history of the available bandwidth of the satellite line determined by the line band determination unit 16 in the past. Since it is configured to correct the bandwidth, it becomes possible to optimize the amount of transmission in a bandwidth that anticipates a trend of deterioration or recovery of the line bandwidth, and it is possible to more reliably prevent data packets from being lost. There is an effect.

In the first embodiment, the reception quality analysis unit 14 of the line bandwidth calculation unit 13 calculates only the packet reception rate RR _i as the packet reception quality. However, the present invention is not limited to this. For example, the packet reception rate RR _i , the packet loss rate, and the fluctuation (jitter value) of the reception interval may be calculated, and for example, the sum of these may be calculated as the packet reception quality.

Here, the packet loss rate includes the number of data packets transmitted from the data packet transmitting unit 11 and the number of data packets that could not be received by the local data packet receiving unit 12 (number of missing data packets). Is the ratio. In order to identify the number of lost packets on the receiving side, the sequence number is described in the header of the data packet transmitted from the data packet transmitting unit 11.
The jitter value indicates fluctuations in the packet transmission interval and the reception interval. Normally, in a wireless line, error correction measures are taken in a lower communication layer in order to correct bit errors due to radio wave interference and the like. If the communication status of the line is poor, the bit error occurrence rate increases, and the time spent for error correction processing increases, resulting in an increased jitter value.

Also, the reception quality analysis unit 14 of the line bandwidth calculation unit 13 considers the bit error rate and the burst error rate in addition to the packet reception rate RR _i , the packet loss rate, and the fluctuation (jitter value) of the reception interval. May be.
The bit error rate and the burst error rate are determined by comparing the bit value of the data packet transmitted from the data packet transmitting unit 11 with the bit value of the data packet received by the local data packet receiving unit 12, and how many bits It can be calculated by checking whether the value has changed and how many bit errors have occurred continuously.

Embodiment 2. FIG.
FIG. 3 is a block diagram showing a radio transmission system according to Embodiment 2 of the present invention. In the figure, the same reference numerals as those in FIG.
The line analysis packet receiving unit 19 is a network interface device composed of, for example, a radio or an antenna, and performs processing for receiving the line analysis packet transmitted from the line analysis packet transmitting unit 22 of the packet receiving terminal 2. carry out. The line analysis packet receiving unit 19 constitutes a line analysis packet receiving means.
The line analysis packet transmission unit 22 is a network interface device including, for example, a wireless device, an antenna, and the like, and performs a process of transmitting the line analysis packet to the packet transmission terminal 1.
FIG. 4 is a flowchart showing the processing contents of the wireless transmission system according to the second embodiment of the present invention.

In the first embodiment, the data packet transmitted from the data packet transmitting unit 11 of the packet transmitting terminal 1 is received by the local data packet receiving unit 12 of the packet transmitting terminal 1, so that the line bandwidth calculating unit 13 In the first embodiment, when a satellite line is used as a wireless line, the line band is calculated from the communication state between the packet transmission terminal 1 and the satellite.
Therefore, in the second embodiment, not only the communication status between the packet transmitting terminal 1 and the satellite but also the communication status between the packet receiving terminal 2 and the satellite is taken into consideration, so that a more appropriate line bandwidth is calculated. Yes.

Next, the operation will be described.
First, the data packet transmitting unit 11 of the packet transmitting terminal 1 transmits a data packet to the packet receiving terminal 2 using an IP multicast address using a satellite line (step ST31).
The data packet receiving unit 21 of the packet receiving terminal 2 receives the data packet transmitted from the packet transmitting terminal 1 by participating in the same multicast address (also referred to as a multicast group) as the IP multicast address (step ST51, ST52).

Further, the line analysis packet transmitter 22 of the packet receiving terminal 2 receives the data packet transmitted from the packet transmitting terminal 1 by the data packet receiving unit 21 and sends the line analyzing packet to the packet transmitting terminal 1 at predetermined intervals. Transmit repeatedly (steps ST53 and ST54).
Here, the line analysis packet may be any data. For example, a data packet having all bit values “0” may be transmitted, or if there is data to be transmitted to the packet transmitting terminal 1 side. The data may be packetized and transmitted.
Further, in order to further improve the prediction accuracy of the line bandwidth in the packet transmitting terminal 1, the reception quality of the data packet received by the data packet receiving unit 21 may be transmitted.
However, the line analysis packet continues to be transmitted at a predetermined size and interval.

The line analysis packet receiver 19 of the packet transmission terminal 1 receives the line analysis packet transmitted from the line analysis packet transmitter 22 of the packet reception terminal 2 (step ST32).
When the line analyzing packet receiving unit 19 receives the line analyzing packet transmitted from the line analyzing packet transmitting unit 22 of the packet receiving terminal 2, the line band calculating unit 13 of the packet transmitting terminal 1 receives the line analyzing packet. The reception quality is calculated, and the usable bandwidth of the satellite line is calculated from the reception quality.
The processing contents of the line bandwidth calculation unit 13 will be specifically described below.

When the line analysis packet receiving unit 19 receives the line analysis packet, the reception quality analysis unit 14 of the line bandwidth calculation unit 13 receives the reception rate RR _i and the packet loss rate PL that are indicators of the reception quality of the line analysis packet. _i , Jitter J _i which is fluctuation of the reception interval is calculated (step ST33).
As in the first embodiment, only the reception rate RR _i may be calculated. However, the line analysis packet received by the line analysis packet receiver 19 is transmitted from the data packet transmitter 11. The packet loss rate PL _i and the jitter J _i are also different because it may be difficult to calculate the line bandwidth only with the reception rate RR _i of the line analysis packet. I am trying to calculate.

Here, the difference in properties means an asymmetric network in which line resources allocated are different between a communication line from the packet transmission terminal 1 to the packet reception terminal 2 and a communication line from the packet reception terminal 2 to the packet transmission terminal 1. And so on.
For example, a data packet from the packet transmission terminal 1 to the packet reception terminal 2 is transmitted at 1 Mbps, but a line analysis packet from the packet reception terminal 2 to the packet transmission terminal 1 has an upper limit set at 100 kbps in order to reduce communication costs. The case where it is done is considered.
At this time, even if the actual line bandwidth of the data packet from the packet transmission terminal 1 to the packet reception terminal 2 decreases from 1 Mbps to half of 500 kbps, the line analysis packet from the packet reception terminal 2 to the packet transmission terminal 1 is 100 kbps. You may be able to continue receiving at. For this reason, it is conceivable that an accurate line bandwidth of a data packet cannot be calculated only with the reception rate RR _i of the line analysis packet.
For these reasons, the reception quality analysis unit 14 of the packet transmission terminal 1 according to the second embodiment calculates not only the line analysis packet reception rate RR _i but also the packet loss rate PL _i and the jitter J _i. ing.

Here, the packet loss rate can be received by the number of line analysis packets transmitted from the line analysis packet transmitting unit 22 of the packet receiving terminal 2 and the line analysis packet receiving unit 19 of the packet transmitting terminal 1. This is the ratio of the number of line analysis packets that were not present (number of missing line analysis packets). In order to identify the number of lost packets on the packet transmission terminal 1 side, a sequence number is written in the header of the line analysis packet transmitted from the line analysis packet transmitter 22 of the packet reception terminal 2. Like that.
The jitter value indicates fluctuations in the packet transmission interval and the reception interval. Normally, in a wireless line, error correction measures are taken in a lower communication layer in order to correct bit errors due to radio wave interference and the like. If the communication status of the line is poor, the bit error occurrence rate increases, and the time spent for error correction processing increases, resulting in an increased jitter value.

The line bandwidth determination unit 16 of the line bandwidth calculation unit 13 analyzes the reception quality of the line analysis packet by the reception quality analysis unit 14 (for example, the line sum is obtained from the reception rate RR _i , the packet loss rate PL _i and the jitter J _i (Referred to as the reception quality of the analysis packet), with reference to the correspondence relationship managed in the database 15, the actual bandwidth of the satellite line corresponding to the reception quality of the line analysis packet is specified, and the actual bandwidth of the satellite link is determined. It is determined as an available band SR _i .
In the database 15, for example, when the correspondence relationship shown below is managed, for example, if the reception quality of the line analysis packet matches the reception quality R3, the satellite line corresponding to the reception quality of the line analysis packet Is determined to be S3, and the usable bandwidth SR _i of the satellite line is determined to be S3.
Alternatively, if the reception quality of the line analysis packet is between the reception quality R2 and the reception quality R3 and the reception quality of the line analysis packet is closer to the reception quality R2 than the reception quality R3, the reception quality of the line analysis packet The actual bandwidth of the satellite line corresponding to is specified as S2, and the available bandwidth SR _i of the satellite line is determined as S2.

Correspondence relationship managed in database 15 Reception quality Actual bandwidth of satellite line R1 → S1
R2 → S2
R3 → S3
R4 → S4
:
:
RN → SN

In the second embodiment, the usable bandwidth SR _i of the satellite line determined by the line band determining unit 16 is output to the line band correcting unit 17, but without being output to the line band correcting unit 17, You may make it output to the data transmission amount control part 18. FIG.

When the line bandwidth correction unit 17 of the line bandwidth calculation unit 13 receives the usable bandwidth SR _i of the satellite line from the line bandwidth determination unit 16, as in the first embodiment, the use of the satellite line determined in the past is used. The available bandwidth SR _i of the satellite link determined this time is corrected according to the history of the available bandwidth.
That is, the line band correction unit 17 stores the line band SR _i determined this time by the line band determination unit 16 as a history (step ST35), and the line band SR _i currently determined by the line band determination unit 16 and the previous time. A difference D _i (= SR _i−1 −SR _i ) from the determined line bandwidth SR _i−1 is calculated (step ST36).

Here, the greater the difference D _{i, the} worse the line quality, and the difference history (... D _i−3 , D _i−2 , D _i−1 , D _i ) becomes larger. It can be assumed that the line quality is getting worse.
On the other hand, if the difference history (... D _i-3 , D _i-2 , D _i-1 , D _i ) has become smaller (close to 0), it is assumed that the line quality has recovered. can do.

Next, the line bandwidth correction unit 17 calculates a line quality evaluation value W from the difference histories D _i-2 , D _i-1 , D _i and the currently determined line bandwidth SR _i as shown below. Then, the evaluation value W is compared with a predetermined threshold value α (step ST38).
W = ((D _i + D _i-1 + D _i-2 ) / 3) / SR _i
If the evaluation value W is greater than the threshold value α, the line bandwidth correction unit 17 assumes that the line quality has deteriorated, and the line bandwidth SR _i determined this time becomes a somewhat smaller value as shown below. (Step ST39).
SR _i = SR _i × (1-W)
On the other hand, if the evaluation value W is equal to or less than the threshold value α, it is assumed that the line quality has been recovered, and correction is made so that the line band SR _i determined this time becomes a somewhat large value as shown below ( Step ST40).
SR _i = SR _i × β where β> 1.0

When the data transmission amount control unit 18 of the packet transmission terminal 1 receives the usable bandwidth SR _i of the satellite channel from the channel bandwidth correction unit 17 (or the channel bandwidth determination unit 16) of the channel bandwidth calculation unit 13, the channel bandwidth The transmission amount of the data packet transmitted from the data packet transmission unit 11 is controlled according to SR _i .
That is, the data transmission amount control unit 18 adjusts the number, interval, and size of the transmission target packets so that the transmission rate of the data packets transmitted from the data packet transmission unit 11 matches the line bandwidth SR _i (step). ST41).
For example, when the packet transmission terminal 1 transmits live video captured by a camera, the data transmission amount control unit 18 functions as a video or audio encoder, and the line bandwidth SR _i output from the line bandwidth correction unit 17. Is set to the target encoding rate of the encoder to perform encoding.
Thereafter, the processes of steps ST31 to ST42 are repeated until the data transmission is completed (step ST43).

  As is apparent from the above, according to the second embodiment, the line analysis packet receiving unit 19 that receives the line analysis packet transmitted from the line analysis packet transmitting unit 22 of the packet receiving terminal 2, and the line analysis And a line bandwidth calculation unit 13 for calculating a usable bandwidth of the wireless line from the reception quality of the line analysis packet received by the packet reception unit 19, and the data transmission amount control unit 18 calculates by the line bandwidth calculation unit 13 Since the transmission amount of the data packet transmitted from the data packet transmission unit 11 is controlled according to the available bandwidth, the transmission amount of the data packet can be optimized. As a result, it is possible to prevent data packets from being lost.

  Further, according to the second embodiment, the line bandwidth correction unit 17 can use the satellite line determined this time according to the history of the available bandwidth of the satellite line determined by the line band determination unit 16 in the past. Since it is configured to correct the bandwidth, it becomes possible to optimize the amount of transmission in a bandwidth that anticipates a trend of deterioration or recovery of the line bandwidth, and it is possible to more reliably prevent data packets from being lost. There is an effect.

  The line bandwidth calculation unit 13 according to the second embodiment predicts the available line bandwidth when transmitting a data packet from a line analysis packet different from the data packet. In comparison, although the prediction accuracy may be lowered, the more accurate the line bandwidth can be predicted as the amount of reception analysis information and the number of items increase.

In the second embodiment, the case where the reception quality analysis unit 14 of the line bandwidth calculation unit 13 calculates the packet reception rate RR _i , the packet loss rate PL _i and the jitter J _i has been described. In addition, the burst error rate may be taken into account.
The bit error rate and the burst error rate are the bit value of the line analysis packet transmitted from the line analysis packet transmitter 22 of the packet receiving terminal 2 and the line analysis packet received by the line analysis packet receiver 19. It can be calculated by comparing the bit value and examining how much the bit value has changed and how many bit errors have occurred continuously.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the radio | wireless transmission system by Embodiment 1 of this invention. It is a flowchart which shows the processing content of the radio | wireless transmission system by Embodiment 1 of this invention. It is a block diagram which shows the radio | wireless transmission system by Embodiment 2 of this invention. It is a flowchart which shows the processing content of the radio | wireless transmission system by Embodiment 2 of this invention.

Explanation of symbols

  1 packet transmitting terminal, 2 packet receiving terminal, 3 network, 11 data packet transmitting section (data packet transmitting means), 12 own station data packet receiving section (own station data packet receiving means), 13 line bandwidth calculating section (line bandwidth calculating) Means), 14 reception quality analysis section, 15 database, 16 line bandwidth determination section, 17 line bandwidth correction section, 18 data transmission volume control section (transmission volume control means), 19 line analysis packet reception section (line analysis packet reception) Means), 21 data packet receiver, 22 line analysis packet transmitter.

Claims (9)

  In a wireless transmission system in which a packet transmitting terminal transmits a data packet to a packet receiving terminal using a wireless line, the packet transmitting terminal transmits a data packet to the packet receiving terminal using a wireless line. A local data packet receiving means for receiving a data packet which is transmitted from the data packet transmitting means and then looped back on a wireless line; and a wireless packet based on the reception quality of the data packet received by the local data packet receiving means. A line bandwidth calculating means for calculating a usable bandwidth of the line, and a transmission amount for controlling a transmission amount of the data packet transmitted from the data packet transmitting means in accordance with the available bandwidth calculated by the line bandwidth calculating means A wireless transmission system comprising: a control unit;   In a wireless transmission system in which a packet transmitting terminal transmits a data packet to a packet receiving terminal using a wireless line, the packet transmitting terminal transmits a data packet to the packet receiving terminal using a wireless line. A line analysis packet receiving means for receiving the line analysis packet transmitted from the packet receiving terminal, and the use of the radio line from the reception quality of the line analysis packet received by the line analysis packet receiving means. Line bandwidth calculating means for calculating a possible bandwidth, and transmission amount control means for controlling the amount of data packets transmitted from the data packet transmitting means in accordance with the available bandwidth calculated by the line bandwidth calculating means; A wireless transmission system comprising:   A data packet transmitting means for transmitting a data packet to a packet receiving terminal using a wireless line; and a local data packet receiving means for receiving a data packet transmitted from the data packet transmitting means and then returned by the wireless line; A line bandwidth calculating means for calculating a usable bandwidth of the radio line from the reception quality of the data packet received by the local station data packet receiving means, and a usable bandwidth calculated by the line bandwidth calculating means. A packet transmission terminal comprising: a transmission amount control unit that controls a transmission amount of a data packet transmitted from the data packet transmission unit.   Data packet transmitting means for transmitting a data packet to a packet receiving terminal using a wireless line, line analyzing packet receiving means for receiving a line analyzing packet transmitted from the packet receiving terminal, and the line analyzing packet A line bandwidth calculating means for calculating a usable bandwidth of the wireless line from the reception quality of the packet for line analysis received by the receiving means, and the data packet according to the available bandwidth calculated by the line bandwidth calculating means A packet transmission terminal comprising: a transmission amount control unit that controls a transmission amount of a data packet transmitted from the transmission unit.   The line bandwidth calculation means refers to the reception quality analysis unit that analyzes the reception quality of the packet, the database that manages the correspondence between the actual bandwidth of the wireless line and the reception quality, and the correspondence that is managed in the database And a line bandwidth determining unit that identifies the actual bandwidth of the wireless line corresponding to the reception quality analyzed by the reception quality analyzing unit, and determines the actual bandwidth as a usable bandwidth of the wireless channel. The packet transmission terminal according to claim 3 or 4, characterized by the above.   The line bandwidth correction unit for correcting the available bandwidth of the wireless line determined this time according to the history of the available bandwidth of the wireless line determined in the past by the line bandwidth determination unit. 5. The packet transmission terminal according to 5.   6. The packet transmission terminal according to claim 5, wherein the reception quality analysis unit analyzes the reception rate of the packet as the reception quality of the packet.   6. The packet transmission terminal according to claim 5, wherein the reception quality analysis unit analyzes fluctuations in the packet reception rate, packet loss rate, and reception interval as the packet reception quality.   6. The packet transmission terminal according to claim 5, wherein the reception quality analysis unit analyzes a packet reception rate, a packet loss rate, a fluctuation in reception interval, a bit error rate, and a burst error rate as the packet reception quality.

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