JP5256092B2 - Transmission path characteristic measuring apparatus and transmission path characteristic measuring system using the same - Google Patents

Description

  The present invention relates to a transmission path characteristic measurement technique, and more particularly to a transmission path characteristic measurement apparatus that measures a transmission path characteristic between radio apparatuses and a transmission path characteristic measurement system using the transmission path characteristic measurement apparatus.

  When the wireless system includes a plurality of transmission units and one reception unit, it is required to reduce the collision probability between signals transmitted from each of the plurality of transmission units. In particular, when each transmission unit measures time independently with a clock incorporated in each, and transmits a signal according to the time measured, the time of each transmission unit clock is different. There is a possibility that the transmission units transmit signals at the same frequency at the same time. As a result, interference occurs between the transmitted signals, and communication to the receiving unit fails. For this reason, the plurality of transmission units have a common time frame and transmit signals in response thereto.

Japanese Patent Laid-Open No. 2001-127585

  In order to reduce the collision probability between signals transmitted from multiple transmission units, it is important that the multiple transmission units have a common time frame, that is, the timing between the multiple transmission units is synchronized. . In such synchronization, for example, the receiving unit transmits a signal indicating a reference timing (hereinafter referred to as “reference timing”), and a plurality of transmitting units are synchronized with the timing indicated by the signal. It is realized by doing. However, when the receiving unit is a measuring device, the measuring device generally does not have a function of transmitting a signal indicating the reference timing. In addition, it is desirable that timing synchronization be simplified.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a technique for easily establishing timing synchronization even when a signal indicating a reference timing is not transmitted.

  In order to solve the above problems, a transmission line characteristic measuring apparatus according to an aspect of the present invention sequentially increases a counter value in a range from a first value to a second value according to a clock, and the counter value is a second value. When the value is reached, a signal is sent from each of a clock counter that repeats an increase in the counter value by returning the counter value to the first value and a plurality of transmission devices equipped with a clock counter having the same range as the clock counter. A receiving unit that receives the signal, a counter value included in each signal received by the receiving unit, and an extraction unit that extracts a counter value in a clock counter mounted on a transmission device that has transmitted the signal; Based on the counter value extracted in step 1 and the counter value in the clock counter, a deriving unit for deriving a correction value for the counter value for each transmitting device, and a deriving unit An instruction unit that instructs each transmission device to correct the counter value using the correction value derived in this manner, and after the counter value is corrected by the instruction unit, transmission between each transmission device based on a signal from each transmission device A measurement unit that measures road characteristics.

  According to this aspect, the correction value for the counter value in the clock counter mounted on each transmission device is derived, and the correction of the counter value based on the correction value is instructed to each transmission device. Timing synchronization can be established.

  Another aspect of the present invention is a transmission line characteristic measurement system. The transmission path characteristic measuring system sequentially increases the counter value in the range from the first value to the second value according to the clock, and when the counter value reaches the second value, the counter value is changed to the first value. A transmission path characteristic measurement device equipped with a clock counter that returns and repeats incrementing the counter value, and a clock counter that has the same range as the clock counter installed in the transmission path characteristic measurement device, and the counter value at the clock counter And a plurality of transmission devices that transmit a signal including. The transmission path characteristic measuring device includes a receiving unit that receives signals from each of a plurality of transmitting devices, an extracting unit that extracts a counter value included in each signal received by the receiving unit, and a counter value extracted by the extracting unit And a deriving unit for deriving a correction value of the counter value for each transmitting device based on the counter value in the clock counter, and an instruction for instructing each transmitting device to correct the counter value by the correction value derived in the deriving unit And a measurement unit that measures the channel characteristics between the transmitters based on signals from the transmitters after the counter value is corrected by the instruction unit.

  According to this aspect, the transmission path characteristic measurement device derives a correction value for the counter value in the clock counter mounted on each transmission device, and instructs each transmission device to correct the counter value by the correction value. Even without this, timing synchronization can be easily established.

  Yet another embodiment of the present invention is a transmission path characteristic measuring apparatus. This device sequentially increases the counter value in the range from the first value to the second value according to the clock, and when the counter value reaches the second value, the counter value is returned to the first value and the counter value is reached. Included in each of the signals received by the receiving unit and the receiving unit that receives the signal from each of the plurality of transmission devices equipped with the clock counter that repeats the increase and the clock counter having the same range as the clock counter An extraction unit that extracts a counter value and a counter value in a clock counter mounted on a transmission device that has transmitted the signal, and uses one of the counter values extracted in the extraction unit as a reference value. A correction unit that corrects the counter value, a remaining counter value extracted by the extraction unit, a counter value corrected by the correction unit, Originally, a derivation unit for deriving a correction value of the counter value for a transmission device different from the transmission device that is a transmission source of the reference value in the correction unit, and correction of the counter value by the correction value derived in the derivation unit, Each transmitting device based on a signal from each transmitting device after correcting the counter value in the instructing unit after instructing to a transmitting device different from the transmitting device that is the transmission source of the reference value in the correcting unit And a measurement unit for measuring transmission line characteristics between the two.

  According to this aspect, the counter value is corrected to match the counter value in one transmission device, the correction value for the counter value in the remaining transmission devices is derived, and the correction of the counter value by the correction value is instructed. Even if there is no reference timing, timing synchronization can be easily established.

  Yet another embodiment of the present invention is a transmission line characteristic measurement system. The transmission path characteristic measuring system sequentially increases the counter value in the range from the first value to the second value according to the clock, and when the counter value reaches the second value, the counter value is changed to the first value. A transmission path characteristic measurement device equipped with a clock counter that returns and repeats incrementing the counter value, and a clock counter that has the same range as the clock counter installed in the transmission path characteristic measurement device, and the counter value at the clock counter A first transmission device that transmits a signal that includes a clock counter and a clock counter that has the same range as the clock counter mounted in the transmission path characteristic measurement device, and a signal that includes the counter value in the clock counter And at least one second transmission device for transmission. The transmission path characteristic measuring device includes a receiving unit that receives signals from each of the first transmitting device and at least one second transmitting device, and an extracting unit that extracts a counter value included in each signal received by the receiving unit. And a correction unit that corrects the counter value in the clock counter based on the counter value from the first transmission device among the counter values extracted in the extraction unit, and the rest of the counter values extracted in the extraction unit A derivation unit for deriving a correction value of the counter value for at least one second transmission device based on the counter value corrected by the correction unit, and at least one correction of the counter value by the correction value derived by the derivation unit. From the first transmission device and at least one second transmission device after correcting the counter value in the instruction unit Based on No., and a measuring unit for measuring a channel characteristic between at least one of the second transmitter and the first transmission device.

  According to this aspect, the transmission path characteristic measuring device corrects the counter value so as to match the counter value in one transmitting device, derives the correction value for the counter value in the remaining transmitting devices, and determines the counter value based on the correction value. Therefore, even if there is no reference timing, timing synchronization can be easily established.

  It should be noted that any combination of the above-described constituent elements and a conversion of the expression of the present invention between a method, an apparatus, a system, a recording medium, a computer program, etc. are also effective as an aspect of the present invention.

  According to the present invention, timing synchronization can be easily established even when a signal having a reference timing is not transmitted.

It is a figure which shows the structure of the measurement system which concerns on the Example of this invention. It is a figure which shows the structure of the measuring apparatus of FIG. It is a figure which shows the data structure of the table memorize | stored in the measurement part of FIG. It is a figure which shows the structure of the 1st transmitter of FIG. It is a flowchart which shows the correction | amendment procedure in the measuring apparatus of FIG. It is a figure which shows the structure of the measuring apparatus which concerns on the modification of this invention. It is a flowchart which shows the correction | amendment procedure in the measuring apparatus of FIG.

  Before describing the present invention specifically, an outline will be given first. Embodiments of the present invention relate to a measurement system including a plurality of transmission devices and a measurement device that measures transmission path characteristics between the transmission devices. Each transmission apparatus is provided with a plurality of antennas, and the measurement apparatus is also provided with a plurality of antennas. The measurement apparatus measures transmission path characteristics between the antennas of the transmission apparatus and the antennas of the measurement apparatus. For example, if the number of transmission devices is “2”, the number of antennas of each transmission device is “2”, and the number of antennas of the measurement device is “4”, the measurement device has a transmission path characteristic of “16”. taking measurement. Such transmission path characteristics should be measured at different timings. For this reason, it is required that the timings are synchronized among a plurality of transmission apparatuses and signals are transmitted at different timings. As described above, even when the measurement apparatus does not transmit the reference timing, the measurement system according to the present embodiment performs the following process in order to easily establish timing synchronization between them.

  The measuring apparatus according to the present embodiment includes a clock counter having a predetermined range, and periodically increases the counter value of the clock counter according to the input clock. Hereinafter, a period specified in a predetermined range is defined as a “frame”. Each of the plurality of transmitting devices also includes a clock counter having the same range as the clock counter of the measuring device, and increases the counter value as in the measuring device. In an initial state such as immediately after startup, the plurality of transmission devices and the measurement devices are not synchronized, and thus have different counter values. One transmitter (hereinafter referred to as “first transmitter”) transmits a radio signal including a counter value at the time of transmission at an arbitrary timing. The measuring device derives a difference between the counter value included in the received radio signal and its own counter value.

  Here, the measurement device and the transmission device also correspond to a wireless system such as a mobile phone system, and the measurement device transmits a difference value to the first transmission device in the mobile phone system. The first transmission device corrects the counter value based on the difference value. Thereafter, another transmitter (hereinafter referred to as “second transmitter”) also performs the same operation, so that each of the plurality of transmitters is synchronized with the timing of the measuring device. As a result, these frame timings are synchronized. Further, the frame is divided into slots corresponding to the number of transmission path characteristics to be measured, in the above-described example, “16” slots. In a plurality of transmission apparatuses and measurement apparatuses, a combination of an antenna that should transmit a signal and an antenna that should receive a signal is predetermined for each slot. As described above, when the frame timing is synchronized, the timing of each slot is also specified, so that a signal is transmitted from only one antenna in a predetermined slot. As a result, signal collision is reduced, and the measurement accuracy of the transmission path characteristics is improved.

  FIG. 1 shows a configuration of a measurement system 100 according to an embodiment of the present invention. The measurement system 100 includes a first transmission device 10a, a second transmission device 10b, a measurement device 12, and a reference signal generator 14 that are collectively referred to as a transmission device 10, and a first reference signal generator 14a and a second reference signal generation. 14b and a third reference signal generator 14c. The first transmission device 10a includes a first transmission antenna 16a, a second transmission antenna 16b, and a first communication antenna 20a. The second transmission device 10b includes a third transmission antenna 16c, a fourth transmission antenna 16d, and a second communication antenna. 20b is included. The measuring device 12 includes a first receiving antenna 18a, a second receiving antenna 18b, a third receiving antenna 18c, a fourth receiving antenna 18d, and a third communication antenna 20c, which are collectively referred to as the receiving antenna 18. Here, the first transmission antenna 16a, the second transmission antenna 16b, the third transmission antenna 16c, and the fourth transmission antenna 16d are collectively referred to as the transmission antenna 16, and are referred to as the first communication antenna 20a, the second communication antenna 20b, and the third communication. The antenna 20c is collectively referred to as the communication antenna 20.

  A communication antenna 20 in FIG. 1 is an antenna corresponding to a mobile phone system. Here, the first transmission device 10a, the second transmission device 10b, and the measurement device 12 all correspond to terminal devices in the mobile phone system. Therefore, signals transmitted from each of the first communication antenna 20a, the second communication antenna 20b, and the third communication antenna 20c reach the other communication antenna 20 via a base station device (not shown). However, in FIG. 1, in order to simplify the drawing, the display of the base station apparatus is omitted. Therefore, in FIG. 1, it is shown that direct communication is performed between the communication antennas 20, but actually communication is performed via the base station apparatus.

  The reference signal generator 14 generates a clock signal having a predetermined frequency as a reference signal. The reference signal generator 14 generates a clock signal using cesium or rubidium. For example, the frequency of the clock signal is set to 102.4 MHz. The reference signal generator 14 outputs a clock signal. The measuring device 12 receives the clock signal from the reference signal generator 14. The measuring device 12 includes a clock counter and inputs a clock signal to the clock counter. The clock counter sequentially increases the counter value in the range from the first value to the second value according to the clock signal.

  Further, when the counter value reaches the second value, the clock counter returns the counter value to the first value and repeats incrementing the counter value. For example, the first value is set to “0” and the second value is set to “16383”. A period until the counter value changes from the first value to the second value is a frame. Each of the plurality of transmission devices 10 also receives the clock signal from the reference signal generator 14. Each transmitting device 10 is equipped with a clock counter having the same range as the clock counter mounted on the measuring device 12. In order to describe the processing in the measurement system 100 in chronological order, (1) synchronization processing and (2) measurement processing will be described below in this order.

(1) Synchronization Processing Each transmission device 10 receives an instruction from the measurement device 12 via the communication antenna 20. The instruction is output to the transmission device 10 unit. Each transmission device 10 transmits a radio signal including a counter value of the clock counter from the transmission antenna 16 at different timings according to the instruction. For example, after the radio signal from the first transmission device 10a is transmitted and the counter value difference derivation process in the measurement device 12 is completed, the radio signal from the second transmission device 10b is transmitted. The measurement device 12 receives radio signals from the plurality of transmission devices 10 via the reception antenna 18 at different timings.

  The measuring device 12 extracts a counter value included in the radio signal, and derives a correction value of the counter value for each transmitting device 10 based on the difference between the counter value and the counter value in the clock counter. . The measuring device 12 transmits a packet signal including the correction value from the third communication antenna 20c. Here, the transmission destination of the packet signal including the correction value for the first transmission device 10a is set to the first transmission device 10a. By transmitting the packet signal, the measuring device 12 instructs each transmitting device 10 to correct the counter value by the correction value. The transmission device 10 receives the packet signal from the measurement device 12 via the communication antenna 20. The transmitting apparatus 10 extracts a correction value included in the packet signal, and corrects the counter value of the clock counter with the correction value.

(2) Measurement Process Before describing the measurement process, here, a transmission path to be measured by the measurement system 100 will be described. The first transmission device 10a and the second transmission device 10b are provided with four transmission antennas 16 from the first transmission antenna 16a to the fourth transmission antenna 16d. On the other hand, the measuring device 12 includes four receiving antennas 18 from the first receiving antenna 18a to the fourth receiving antenna 18d. One transmission path is determined by a combination of one transmission antenna 16 and one reception antenna 18. In the case of FIG. 1, 16 combinations are formed, such as a combination of the first transmission antenna 16a and the first reception antenna 18a and a combination of the first transmission antenna 16a and the second reception antenna 18b. In the measurement system 100, the frame is divided into 16 slots according to the number of combinations.

  One slot is defined as a period of “1024” clocks. In addition, one transmission line characteristic is measured in one slot. Further, a combination of the transmission antenna 16 and the reception antenna 18 is associated with each slot in advance. For example, in the first slot of the frame, a signal transmitted from the first transmission antenna 16a (hereinafter referred to as “training signal”) is received by the first reception antenna 18a, and in the next slot, from the first transmission antenna 16a. The transmitted training signal is received by the second receiving antenna 18b. Such a measurement order is stored in advance in the first transmission device 10a, the second transmission device 10b, and the measurement device 12.

  The user instructs the measurement device 12 to start measurement. The measurement device 12 instructs the first transmission device 10a and the second transmission device 10b to start measurement via the third communication antenna 20c. The first transmission device 10a monitors the counter value and detects the timing when the counter value becomes “0”, that is, the timing when a new frame starts. The first transmission device 10a transmits a training signal from the first transmission antenna 16a in the first slot. The training signal has a pattern known to the measuring device 12. The measuring device 12 receives the training signal at the first receiving antenna 18a. The measuring device 12 measures the transmission path characteristics based on the received training signal. When the slot is changed, the same processing is repeated while the combination of the transmission antenna 16 and the reception antenna 18 is changed. That is, the measuring device 12 corrects the counter value, and then measures the transmission path characteristics between each transmitting device 10 based on the training signal from each transmitting device 10.

  FIG. 2 shows the configuration of the measuring device 12. The measuring device 12 is generally referred to as a first receiving antenna 18a, a second receiving antenna 18b, a third receiving antenna 18c, a fourth receiving antenna 18d, a third communication antenna 20c, and a radio unit 30. First radio unit 30a, second radio unit 30b, third radio unit 30c, fourth radio unit 30d, first quadrature detection unit 32a, second quadrature detection unit 32b, third quadrature detection unit collectively called quadrature detection unit 32 32c, a fourth orthogonal detection unit 32d, a measurement unit 34, an operation unit 36, an adjustment unit 38, a clock counter 40, a communication unit 42, and a control unit 44. The adjustment unit 38 includes a demodulation unit 46, an extraction unit 48, and a derivation unit 50.

  The clock counter 40 receives a clock signal from a third reference signal generator 14c (not shown). The clock counter 40 sequentially increases the counter value based on the clock signal. As described above, the counter value is defined to be in the range from the first value to the second value, and is also defined to return to the first value when the second value is reached. The clock counter 40 outputs the counter value to the measurement unit 34 and the derivation unit 50. This also corresponds to outputting frame timing and slot timing. In the following, in order to clarify the correspondence with FIG. 1, (1) synchronization processing and (2) measurement processing will be described in this order.

(1) Synchronization processing The operation unit 36 is configured by an interface such as a button and receives various instructions from the user. The operation unit 36 outputs the received instruction to the measurement unit 34. The measurement unit 34 has a function for measuring transmission path characteristics, but also has a function for executing processing necessary for measurement of transmission path characteristics. For example, a function for instructing transmission to the transmission apparatus 10 to measure transmission path characteristics and a function for executing synchronization processing. When the measurement unit 34 receives an instruction for causing the transmission device 10 to transmit a radio signal via the operation unit 36, the measurement unit 34 generates a packet signal including a radio signal transmission instruction according to the instruction. Here, the received instruction includes information for specifying the transmission device 10, and the measurement unit 34 specifies the destination of the packet signal based on the information. The measurement unit 34 outputs the packet signal to the communication unit 42. The communication unit 42 corresponds to the mobile phone system, and transmits a packet signal to the transmission device 10 via the third communication antenna 20c. This corresponds to, for example, an instruction to cause the first transmission device 10a to transmit a radio signal.

  The radio unit 30 receives a radio signal from the transmission device 10 via the reception antenna 18. As described above, the wireless signal includes the counter value of the clock counter mounted on the transmission device 10 that is the transmission source. The radio unit 30 performs frequency conversion from a radio frequency to an intermediate frequency for a radio signal. The radio unit 30 outputs a radio signal converted to an intermediate frequency (hereinafter also referred to as “radio signal”) to the quadrature detection unit 32. The quadrature detection unit 32 performs frequency conversion from the intermediate frequency to the baseband on the radio signal by performing quadrature detection on the radio signal from the radio unit 30. Further, the quadrature detection unit 32 performs A / D conversion on a baseband radio signal (hereinafter also referred to as “radio signal”). The quadrature detection unit 32 outputs a radio signal converted to a digital signal (hereinafter also referred to as “radio signal”) to the demodulation unit 46. In general, a baseband signal includes a window component and a quadrature component, and therefore should be indicated by two signal lines. However, here, in order to clarify the drawing, the baseband signal is shown by one signal line.

  The demodulator 46 receives the radio signal from the quadrature detector 32 and demodulates the radio signal. In addition, the demodulator 46 outputs the demodulated signal to the extractor 48. The extraction unit 48 extracts a counter value included in the signal and a counter value in a clock counter mounted on the transmission apparatus 10 that has transmitted the signal. The extraction unit 48 outputs the counter value to the derivation unit 50. The deriving unit 50 inputs the counter value extracted by the extracting unit 48 (hereinafter referred to as “first counter value”) and the counter value at the clock counter 40 (hereinafter referred to as “second counter value”). The deriving unit 50 derives a correction value for the first counter value based on the first counter value and the second counter value. Specifically, the deriving unit 50 derives the correction value by subtracting the first counter value from the second counter value. The deriving unit 50 generates a packet signal including the correction value. In addition, the deriving unit 50 outputs the packet signal and information regarding the transmission device 10 corresponding to the correction value to the communication unit 42.

  The communication unit 42 inputs the packet signal and information related to the transmission device 10 corresponding to the correction value from the derivation unit 50. The communication unit 42 transmits the packet signal from the third communication antenna 20c with the transmission device 10 corresponding to the correction value as the destination of the packet signal. Accordingly, the communication unit 42 instructs the transmission device 10 to correct the counter value using the correction value derived by the deriving unit 50. After such processing, when the operation unit 36 receives an instruction to cause the next transmission device 10 to transmit a radio signal, the measurement unit 34 or the like changes the transmission device 10 to be processed to change the processing described above. Repeatedly. As a result, the deriving unit 50 derives the correction value for each transmission device 10, and the communication unit 42 instructs each transmission device 10 to correct the counter value using the correction value.

(2) Measurement Processing After the communication unit 42 causes each transmitting device 10 to correct the counter value, the operation unit 36 receives a measurement start instruction from the user. The operation unit 36 outputs a measurement start instruction to the measurement unit 34. The measurement unit 34 generates a packet signal including a measurement start instruction. The measurement unit 34 outputs the packet signal to the communication unit 42. The communication unit 42 transmits packet signals from the third communication antenna 20c to the plurality of transmission devices 10. That is, the communication unit 42 instructs the plurality of transmission devices 10 to start measurement.

  The measuring unit 34 stores a table relating to the measurement procedure in advance. FIG. 3 shows the data structure of the table stored in the measurement unit 34. As illustrated, a start timing column 200, an end timing column 202, a transmission antenna column 204, and a reception antenna column 206 are included. A period specified by the counter value shown in the start timing column 200 and the counter value shown in the end timing column 202 corresponds to a slot. For example, the period from the counter value “0” to “1023” corresponds to the first slot, and the period from the counter value “1024” to “2047” corresponds to the next slot. The transmission antenna column 204 and the reception antenna column 206 indicate the transmission antenna 16 and the reception antenna 18 that should be used in each slot. For example, in the first slot, the first transmitting antenna 16a and the first receiving antenna 18a are used, and in the next slot, the first transmitting antenna 16a and the second receiving antenna 18b are used. As described above, the transmission antenna 16 and the reception antenna 18 to be used in each of the 16 slots are defined. The table is also stored in each transmission device 10. Returning to FIG.

  After the measurement start is instructed and the counter value becomes 0, the first receiving antenna 18a and the first radio unit 30a receive a signal from the first transmitting antenna 16a (not shown). The signal includes a known pattern. Hereinafter, the signal is referred to as a “training signal”. The first radio unit 30a performs the same processing as the radio signal on the training signal. The first quadrature detection unit 32a also performs the same processing as the radio signal on the training signal, but measures the training signal converted to a baseband digital signal (hereinafter also referred to as “training signal”). 34. The measurement unit 34 measures the transmission path characteristics between the first transmission antenna 16a and the first reception antenna 18a based on the training signal from the first orthogonal detection unit 32a. For example, a delay profile is measured as the transmission line characteristics. However, since a known technique may be used for the measurement of the delay profile, description thereof is omitted here.

  After the counter value reaches “1024”, the second receiving antenna 18b receives a training signal from the first transmitting antenna 16a (not shown). The second radio unit 30b and the second quadrature detection unit 32b perform the same processing as the first radio unit 30a and the first quadrature detection unit 32a. The measurement unit 34 measures the transmission path characteristics between the first transmission antenna 16a and the second reception antenna 18b based on the training signal from the second orthogonal detection unit 32b. When the counter values shown in the table of FIG. 2 are reached, the transmitting antenna 16 and the receiving antenna 18 are switched, and the same processing is repeated. Therefore, the third radio unit 30c and the fourth radio unit 30d execute the same processing as the first radio unit 30a, and the third quadrature detection unit 32c and the fourth quadrature detection unit 32d are the same as the first quadrature detection unit 32a. A similar process is executed. Finally, the measurement unit 34 measures the transmission line characteristic of “16”. The control unit 44 controls the timing of the entire measuring device 12.

  This configuration can be realized in terms of hardware by a CPU, memory, or other LSI of any computer, and in terms of software, it can be realized by a program loaded in the memory, but here it is realized by their cooperation. Draw functional blocks. Accordingly, those skilled in the art will understand that these functional blocks can be realized in various forms by hardware only, software only, or a combination thereof.

  FIG. 4 shows a configuration of the first transmission device 10a. The first transmission device 10a includes a measurement generation unit 60, a first orthogonal modulation unit 62a, which is collectively referred to as an orthogonal modulation unit 62, a second orthogonal modulation unit 62b, a first wireless unit 64a, which is collectively referred to as a wireless unit 64, and a second. A radio unit 64b, a clock counter 66, a correction unit 68, a communication unit 70, an adjustment generation unit 72, and a control unit 74 are included. Note that the second transmission device 10b of FIG. 1 also has the same configuration as that of FIG. As described above, the clock counter 66 increases the counter value in the same range as the clock counter 40 of FIG. 2 based on the clock signal from the first reference signal generator 14a (not shown). The clock counter 66 sequentially outputs counter values to the measurement generation unit 60 and the adjustment generation unit 72. 4 will be described in the order of (1) synchronization processing and (2) measurement processing in accordance with the descriptions of FIGS.

(1) Synchronization processing The communication unit 70 corresponds to a mobile phone system, and receives a packet signal from the measurement device 12 (not shown) via the first communication antenna 20a. The communication unit 70 demodulates the received packet signal and outputs the demodulated packet signal (hereinafter also referred to as “packet signal”) to the measurement generation unit 60, the correction unit 68, and the adjustment generation unit 72. When the packet signal includes a radio signal transmission instruction, the adjustment generation unit 72 extracts the radio signal transmission instruction. When the adjustment generation unit 72 extracts the radio signal transmission instruction, the adjustment generation unit 72 acquires the counter value from the clock counter 66. In addition, the adjustment generation unit 72 generates a radio signal including the counter value, and outputs the radio signal to the quadrature modulation unit 62.

  The orthogonal modulation unit 62 converts the radio signal from the baseband to the intermediate frequency by performing orthogonal modulation on the radio signal. The quadrature modulation unit 62 also performs digital / analog conversion. The quadrature modulation unit 62 outputs a radio signal converted to an intermediate frequency (hereinafter also referred to as “radio signal”) to the radio unit 64. The radio unit 64 receives the radio signal from the quadrature modulation unit 62 and performs frequency conversion from the intermediate frequency to the radio frequency on the radio signal. The radio unit 64 amplifies a radio signal converted to a radio frequency (hereinafter also referred to as “radio signal”) and transmits the amplified signal from the transmission antenna 16.

  After the wireless signal is transmitted, the communication unit 70 receives the packet signal from the measurement device 12. When the packet signal includes a correction value, the correction unit 68 extracts the correction value. The correction unit 68 corrects the counter value in the clock counter 66 with the correction value. The clock counter 66 corrects the counter value by adding the correction value to the counter value. Further, the corrected counter value is set as a new counter value.

(2) Measurement processing After the counter value is corrected, the communication unit 70 receives a packet signal from the measurement device 12. When the packet signal includes a measurement start instruction, the measurement generation unit 60 extracts the measurement start instruction. Here, the measurement generation unit 60 stores a table similar to that in FIG. 3 in advance, and when a measurement start instruction is extracted, the related counter value is specified from the table. For example, the measurement generation unit 60 identifies the counter values in the start timing column 200 and the end timing column 202 for the slot in which the transmission antenna column 204 includes the first transmission antenna 16a and the second transmission antenna 16b. . The measurement generator 60 monitors the counter value from the clock counter 66. When the monitored counter value matches the specified counter value, the measurement generation unit 60 transmits a training signal from the corresponding transmission antenna 16.

  For example, in the table of FIG. 3, when the counter value “0” is specified as the start timing, the measurement generation unit 60 detects that the counter value of the clock counter 66 has become “0”. A training signal is output to the quadrature modulation unit 62a. The first orthogonal modulation unit 62a and the first radio unit 64a perform the same processing as before and transmit a training signal from the first transmission antenna 16a. The transmission of the training signal is finished by the end timing. Further, when the monitored counter value matches the specified next counter value, the measurement generation unit 60 selects the transmission antenna column 204 based on the transmission antenna column 204 and repeats the same processing. . Such processing is performed over a period of one frame. The control unit 74 controls the timing of the entire first transmission device 10a.

  The operation of the measurement system 100 configured as above will be described. FIG. 5 is a flowchart showing a correction procedure in the measurement apparatus 12. The measurement unit 34 sets i to 1 (S10). The radio unit 30 and the quadrature detection unit 32 receive the radio signal from the i-th transmission device 10i (S12), and the extraction unit 48 extracts the counter value from the radio signal (S14). The deriving unit 50 derives a correction value for the extracted counter value (S16). The deriving unit 50 instructs the i-th transmission device 10i to perform correction via the communication unit 42 (S18). The measurement unit 34 adds 1 to i (S20). If i is not larger than N (N in S22), the process returns to step 12. On the other hand, if i becomes larger than N (Y in S22), the process is terminated.

  Next, a modified example of the present invention will be described. Similar to the embodiment, the modified example relates to a measurement system including a plurality of transmission devices and measurement devices, and even if the measurement device does not transmit a reference timing, timing synchronization between them can be simplified. The purpose is to establish. On the other hand, the measurement apparatus according to the embodiment transmits the correction value to each of the plurality of transmission apparatuses. As a result, each of the plurality of transmitting devices corrects the clock value so as to be synchronized with the clock counter of the measuring device. However, the measuring apparatus according to the modification corrects the counter value so as to be synchronized with the clock counter of one transmission apparatus. Further, the measuring device transmits the correction value to each of the remaining transmitting devices. As a result, each of the remaining transmitting devices corrects the clock value so as to be synchronized with the clock counter of the measuring device.

  FIG. 6 shows the configuration of the measuring apparatus 12 according to a modification of the present invention. As compared with the measurement device 12 of FIG. 2, the measurement device 12 includes a correction unit 52 in the adjustment unit 38. Here, it demonstrates centering on the difference with FIG. 2, and abbreviate | omits description of a measurement process. After transmitting the packet signal including the instruction to transmit the radio signal, the radio unit 30 receives the radio signal from the transmission device 10 via the reception antenna 18. Here, it is assumed that the radio signal from the first transmission device 10a is received first. The radio signal is output to the extraction unit 48 via the radio unit 30, the quadrature detection unit 32, and the demodulation unit 46. The extraction unit 48 extracts the counter value included in the radio signal and outputs the counter value to the derivation unit 50.

  As described above, the derivation unit 50 uses the counter value extracted by the extraction unit 48 (hereinafter referred to as “first counter value”) and the counter value (hereinafter referred to as “the first counter value”). "Second counter value"). The deriving unit 50 derives a correction value for the second counter value based on the first counter value and the second counter value. Specifically, the deriving unit 50 derives the correction value by subtracting the second counter value from the first counter value. The deriving unit 50 outputs the correction value to the correction unit 52. The correction unit 52 corrects the counter value of the clock counter 40 with the correction value. That is, the correction unit 52 corrects the counter value by adding the correction value to the counter value. This corresponds to correcting the counter value in the clock counter 40 using one of the counter values in the plurality of transmission apparatuses 10 as a reference value.

  After the counter value in the clock counter 40 is corrected, the operation unit 36 receives an instruction for causing the next transmission device 10 to transmit a radio signal. The measurement unit 34 changes the transmission device 10 to be processed, and causes the communication unit 42 to transmit a packet signal including an instruction to transmit a radio signal, for example, with the second transmission device 10b as a destination. The radio unit 30 receives a radio signal from the second transmission device 10b via the reception antenna 18. The radio signal is output to the extraction unit 48 via the radio unit 30, the quadrature detection unit 32, and the demodulation unit 46 as before. The extraction unit 48 extracts the counter value included in the radio signal and outputs the counter value to the derivation unit 50.

  As described above, the derivation unit 50 uses the counter value extracted by the extraction unit 48 (hereinafter referred to as “first counter value”) and the counter value (hereinafter referred to as “the first counter value”). "Second counter value"). Here, the second counter value is a value that has already been corrected by the correction unit 52. The deriving unit 50 derives a correction value for the first counter value based on the first counter value and the second counter value. This is equivalent to deriving a correction value similar to that of the deriving unit 50 of FIG. That is, the deriving unit 50 calculates the counter value for the transmission device 10 other than the first transmission device 10a based on the counter value in the transmission device 10 other than the first transmission device 10a and the counter value corrected in the correction unit 52. A correction value is derived.

  The deriving unit 50 generates a packet signal including the correction value. In addition, the deriving unit 50 outputs the packet signal and information regarding the transmission device 10 corresponding to the correction value to the communication unit 42. The communication unit 42 inputs the packet signal and information related to the transmission device 10 corresponding to the correction value from the derivation unit 50. The communication unit 42 transmits the packet signal from the third communication antenna 20c with the transmission device 10 corresponding to the correction value as the destination of the packet signal. Accordingly, the communication unit 42 instructs the transmission device 10 to correct the counter value using the correction value derived by the deriving unit 50. Note that the above processing is also performed for other transmission apparatuses 10. That is, the measuring device 12 corrects the counter value in the clock counter 40 based on the counter value from the first transmission device 10a. Further, the measuring device 12 derives a correction value of the counter value for the transmission device 10 based on the counter value from the transmission device 10 other than the first transmission device 10a and the corrected counter value, and instructs correction. To do.

  FIG. 7 is a flowchart showing a correction procedure in the measurement apparatus 12. The measurement unit 34 sets i to 1 (S40). The radio unit 30 and the quadrature detection unit 32 receive a radio signal from the i-th transmission device 10i (S42), and the extraction unit 48 extracts a counter value from the radio signal (S44). The deriving unit 50 derives a correction value based on the extracted counter value (S46). If i is 1 (Y in S48), the correction unit 52 corrects the counter value with the correction value (S50). On the other hand, if i is not 1 (N in S48), the derivation unit 50 instructs the i-th transmission device 10i to perform correction via the communication unit 42 (S52). The measurement unit 34 adds 1 to i (S54). If i is not greater than N (N in S56), the process returns to step 42. On the other hand, if i becomes larger than N (Y in S56), the process is terminated.

  According to the embodiment of the present invention, based on the counter value of the built-in clock counter, a correction value for the counter value in the clock counter mounted in each transmission device is derived, and the correction of the counter value by the correction value is performed for each counter value. Since the transmitting apparatus is instructed, timing synchronization can be established. Further, since only the counter value is received in order to derive the correction value, the timing synchronization can be easily established without the reference timing. In addition, since timing synchronization is easily established, the process before the measurement process can be easily executed. In addition, since timing synchronization is established, the collision probability of the training signal can be reduced. Further, since the collision probability of the training signal is reduced, the measurement accuracy of the transmission path characteristics can be improved.

  Further, since the counter value of the built-in clock counter is corrected so as to match the counter value in one transmission apparatus, timing synchronization with one transmission apparatus can be easily established. Further, since the counter value of the built-in clock counter is corrected, it is possible to omit sending any instruction to one transmitter. In addition, since any instruction is not transmitted to one transmitter, the process can be easily executed. Also, based on the counter value of the corrected clock counter, the correction value for the counter value in the remaining transmitter is derived, and the correction of the counter value by the correction value is instructed, so timing synchronization is established with the remaining transmitter it can.

  In the above, this invention was demonstrated based on the Example. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to combinations of the respective constituent elements, and such modifications are also within the scope of the present invention.

  In the embodiment of the present invention, each transmission device 10 includes two transmission antennas 16, and the measurement device 12 includes four reception antennas 18. However, the present invention is not limited to this. For example, the number of transmission antennas 16 and the number of reception antennas 18 are not limited to these values, and arbitrary values may be set. According to this modification, the degree of freedom of measurement items can be improved.

  In the embodiment of the present invention, the measurement unit 34 measures the delay profile. However, the present invention is not limited to this. For example, the measurement unit 34 may measure transmission path characteristics other than the delay profile. Specifically, an arrival angle, a launch angle, a Doppler frequency, and the like may be measured as transmission path characteristics. Since a known technique may be used for the measurement of such transmission path characteristics, description thereof is omitted here. According to this modification, various transmission line characteristics can be measured.

  In the modification of the present invention, the measurement unit 34 combines one transmission antenna 16 and one reception antenna 18 and measures the transmission path characteristics for the combination in one measurement. However, the present invention is not limited thereto. For example, the measurement unit 34 may combine a plurality of reception antennas 18 with respect to one transmission antenna 16 and measure transmission path characteristics for a plurality of combinations in one measurement. According to this modification, the measurement period can be shortened.

  In the modification of the present invention, the communication antenna 20 corresponds to a wireless system such as a mobile phone system. However, the present invention is not limited to this. For example, the wireless system may be a wireless LAN (Local Area Network) instead of a mobile phone system. According to this modification, the degree of freedom in adopting the wireless system can be improved.

  DESCRIPTION OF SYMBOLS 10 Transmission apparatus, 12 Measuring apparatus, 14 Reference signal generator, 16 Transmission antenna, 18 Reception antenna, 20 Communication antenna, 30 Radio | wireless part, 32 Quadrature detection part, 34 Measurement part, 36 Operation part, 38 Adjustment part, 40 Clock counter , 42 communication unit, 44 control unit, 46 demodulation unit, 48 extraction unit, 50 derivation unit, 52 correction unit, 60 measurement generation unit, 62 orthogonal modulation unit, 64 radio unit, 66 clock counter, 68 correction unit, 70 communication Part, 72 generating part for adjustment, 74 control part, 100 measuring system.

Claims (4)

According to the clock, the counter value is sequentially increased in the range from the first value to the second value, and when the counter value reaches the second value, the counter value is returned to the first value and the counter value is repeatedly increased. A clock counter,
A receiving unit for receiving a signal from each of a plurality of transmission devices equipped with a clock counter having the same range as the clock counter;
An extraction unit that extracts a counter value included in each signal received by the reception unit and that is a counter value in a clock counter mounted on a transmission device that has transmitted the signal;
A derivation unit for deriving a correction value of the counter value for each transmission device based on the counter value extracted in the extraction unit and the counter value in the clock counter;
An instruction unit for instructing each transmission device to correct the counter value based on the correction value derived by the deriving unit;
After correcting the counter value in the instruction unit, based on the signal from each transmission device, a measurement unit that measures the transmission path characteristics between each transmission device,
A transmission path characteristic measuring apparatus comprising: According to the clock, the counter value is sequentially increased in the range from the first value to the second value, and when the counter value reaches the second value, the counter value is returned to the first value and the counter value is repeatedly increased. A transmission line characteristic measuring device equipped with a clock counter;
A clock counter having the same range as the clock counter mounted in the transmission path characteristic measuring device, and a plurality of transmission devices that transmit a signal including a counter value in the clock counter,
The transmission path characteristic measuring device is
A receiver for receiving signals from each of the plurality of transmitters;
An extraction unit that extracts a counter value included in each signal received by the reception unit;
A derivation unit for deriving a correction value of the counter value for each transmission device based on the counter value extracted in the extraction unit and the counter value in the clock counter;
An instruction unit for instructing each transmission device to correct the counter value based on the correction value derived by the deriving unit;
A transmission path characteristic measuring system comprising: a measuring section that measures a transmission path characteristic with each transmitting apparatus based on a signal from each transmitting apparatus after correcting the counter value in the instruction section . According to the clock, the counter value is sequentially increased in the range from the first value to the second value, and when the counter value reaches the second value, the counter value is returned to the first value and the counter value is repeatedly increased. A clock counter,
A receiving unit for receiving a signal from each of a plurality of transmission devices equipped with a clock counter having the same range as the clock counter;
An extraction unit that extracts a counter value included in each signal received by the reception unit and that is a counter value in a clock counter mounted on a transmission device that has transmitted the signal;
A correction unit that corrects the counter value in the clock counter using one of the counter values extracted in the extraction unit as a reference value;
Based on the remaining counter value extracted in the extraction unit and the counter value corrected in the correction unit, a counter for a transmission device different from the transmission device that is the transmission source of the reference value in the correction unit A derivation unit for deriving a correction value of the value;
An instruction unit that instructs correction of the counter value by the correction value derived in the deriving unit to a transmission device that is different from the transmission device that is a transmission source of the reference value in the correction unit;
After correcting the counter value in the instruction unit, based on the signal from each transmission device, a measurement unit that measures the transmission path characteristics between each transmission device,
A transmission path characteristic measuring apparatus comprising: According to the clock, the counter value is sequentially increased in the range from the first value to the second value, and when the counter value reaches the second value, the counter value is returned to the first value and the counter value is repeatedly increased. A transmission line characteristic measuring device equipped with a clock counter;
A first transmission device that includes a clock counter having the same range as the clock counter mounted in the transmission path characteristic measurement device, and that transmits a signal including the counter value in the clock counter;
A clock counter having the same range as the clock counter mounted in the transmission path characteristic measuring device, and at least one second transmitting device for transmitting a signal including a counter value in the clock counter;
The transmission path characteristic measuring device is
A receiver for receiving signals from each of the first transmitter and the at least one second transmitter;
An extraction unit that extracts a counter value included in each signal received by the reception unit;
Of the counter values extracted in the extraction unit, a correction unit that corrects the counter value in the clock counter based on the counter value from the first transmission device;
A derivation unit for deriving a correction value of the counter value for the at least one second transmission device based on the rest of the counter values extracted by the extraction unit and the counter value corrected by the correction unit;
An instruction unit that instructs the at least one second transmission device to correct the counter value by the correction value derived by the deriving unit;
After the counter value is corrected in the instructing unit, based on signals from the first transmission device and the at least one second transmission device, the first transmission device and the at least one second transmission device A measurement unit for measuring the transmission line characteristics between
A transmission path characteristic measuring system comprising:

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