WO2009128456A1 - 移動局装置および送信電力制御方法 - Google Patents
移動局装置および送信電力制御方法 Download PDFInfo
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- WO2009128456A1 WO2009128456A1 PCT/JP2009/057527 JP2009057527W WO2009128456A1 WO 2009128456 A1 WO2009128456 A1 WO 2009128456A1 JP 2009057527 W JP2009057527 W JP 2009057527W WO 2009128456 A1 WO2009128456 A1 WO 2009128456A1
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- base station
- transmission power
- propagation loss
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- mobile station
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- 230000006854 communication Effects 0.000 abstract description 42
- 238000012937 correction Methods 0.000 description 30
- 238000006243 chemical reaction Methods 0.000 description 12
- 238000010295 mobile communication Methods 0.000 description 10
- 238000010586 diagram Methods 0.000 description 8
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/04—TPC
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/04—TPC
- H04W52/18—TPC being performed according to specific parameters
- H04W52/24—TPC being performed according to specific parameters using SIR [Signal to Interference Ratio] or other wireless path parameters
- H04W52/242—TPC being performed according to specific parameters using SIR [Signal to Interference Ratio] or other wireless path parameters taking into account path loss
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/04—TPC
- H04W52/30—TPC using constraints in the total amount of available transmission power
- H04W52/32—TPC of broadcast or control channels
- H04W52/322—Power control of broadcast channels
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W36/00—Hand-off or reselection arrangements
- H04W36/08—Reselecting an access point
Definitions
- the present invention relates to a mobile station apparatus and a transmission power control method, and particularly to a technique for speeding up handover.
- Next generation PHS Next Generation Personal Handy-phone System
- TDD Time Division Multiple Access / Time Division Duplex: Time Division Multiple Access / Time Division Bidirectional Communication
- OFDMA Orthogonal Frequency Division Multiple Access
- FIG. 9 is a diagram showing a next-generation PHS call sequence.
- the base station transmits a broadcast control channel (BCCH) including its own base station ID and transmission power control information (a negative value indicating a difference between the actual transmission power and the base station maximum transmission power).
- BCCH broadcast control channel
- TCCH Timing Correct Channel
- the base station that has received the timing correction channel from the mobile station first calculates the difference between the reception timing of the timing correction channel and the desired reception timing as a timing correction amount (S206).
- ANCH Anchor Channel
- Each communication channel in the next-generation PHS is composed of a combination of either a time slot by TDMA (for example, a time slot length of 625 ⁇ s) and one of subchannels by OFDMA, and is called a PRU (Physical Resource Unit).
- the base station calculates the correction amount of the mobile station transmission power based on the difference between the reception power and the desired reception power of the timing correction channel (S210), and the timing correction amount calculated in S206 and the ANCH PRU determined in S208
- a signal control channel (downlink SCCH: Signaling Control Channel) including the mobile station transmission power correction amount calculated in S210 is transmitted to the mobile station (S212).
- the mobile station When the mobile station receives the signal control channel from the base station, it acquires the ANCH PRU from the signal control channel (S214). Next, the mobile station corrects the transmission power of the ANCH based on the transmission power correction amount included in the signal control channel (S216), and corrects the transmission timing based on the timing correction amount included in the signal control channel. Thus, frame synchronization in the uplink direction (direction from the mobile station to the base station) is established (S218). Then, the mobile station uses the ANCH PRU acquired in S214 to transmit the uplink ANCH requesting the allocation of the EXCH (Extra Channel) PRU at the transmission power corrected in S216 and the transmission timing corrected in S218. (S220).
- EXCH Extra Channel
- the base station that has received the uplink ANCH from the mobile station determines an EXCH PRU consisting of one or more PRUs (S222), and transmits the downlink ANCH including the determined EXCH PRUs to the mobile station (S224).
- next-generation PHS employing the OFDMA method it is impossible to individually correct the reception timing shift and reception power shift of the uplink signal transmitted from each mobile station on the base station side.
- the inter-symbol interference ISI: Inter-Symbol Interference
- ISI Inter-Symbol Interference
- next-generation PHS even when a mobile station performs handover from a communicating base station to another base station, a sequence similar to the above calling sequence is executed between the mobile station and the handover destination base station. (See S300, S302, S318 to S338 in FIG. 10), there is a problem that time is required for the handover. Further, even in a mobile communication system other than the next-generation PHS, there is a demand for faster handover.
- the present invention has been made in view of the above-described conventional problems, and an object thereof is to provide a mobile communication system, a mobile station apparatus, a base station apparatus, and a handover method that can speed up handover.
- a mobile station apparatus is a mobile station apparatus that performs a handover from a first base station apparatus to a second base station apparatus, and transmits from the second base station apparatus
- a propagation loss calculating means for calculating the propagation loss of the broadcast signal to be transmitted, and an uplink signal for the second base station apparatus based on the known base station desired received power and the propagation loss calculated by the propagation loss calculating means
- Transmission power control means for controlling the transmission power.
- the mobile station apparatus appropriately controls the transmission power of the uplink signal without the handover destination base station apparatus transmitting the transmission power correction amount to the mobile station apparatus. For this reason, transmission of the uplink synchronization burst by the mobile station apparatus and transmission of the transmission power correction amount by the handover destination base station apparatus can be omitted from the handover sequence, and the handover speed can be increased. It is also possible to prevent interference with adjacent cells.
- the propagation loss calculation means measures the received power of the broadcast signal, and based on the measured transmission power of the broadcast signal and the measured received power of the broadcast signal, Calculate the propagation loss of the signal.
- the propagation loss calculation means is configured to perform the notification based on the known maximum transmission power of the base station and the transmission power control information of the notification signal notified from the second base station device. Get the transmission power of the signal.
- the first and second base station devices communicate with the mobile station device using an orthogonal frequency division multiple access scheme.
- a transmission power control method is a transmission power control method for performing handover from a first base station apparatus to a second base station apparatus, and is transmitted from the second base station apparatus.
- a mobile station apparatus is a mobile station apparatus that performs a handover from a first base station apparatus to a second base station apparatus, wherein the first base station apparatus First propagation loss calculation means for calculating a propagation loss of a downlink signal transmitted from the second base station, second propagation loss calculation means for calculating a propagation loss of a broadcast signal transmitted from the second base station apparatus, Based on the uplink signal transmission power to the first base station apparatus and the difference between the propagation loss calculated by the first propagation loss calculation means and the propagation loss measured by the second propagation loss calculation means And transmission power control means for controlling transmission power of the uplink signal to the second base station apparatus.
- the mobile station apparatus appropriately controls the transmission power of the uplink signal without the handover destination base station apparatus transmitting the transmission power correction amount to the mobile station apparatus. For this reason, transmission of the uplink synchronization burst by the mobile station apparatus and transmission of the transmission power correction amount by the handover destination base station apparatus can be omitted from the handover sequence, and the handover speed can be increased. It is also possible to prevent interference with adjacent cells.
- the first propagation loss calculating unit measures the received power of the downlink signal, and based on the transmission power of the downlink signal and the measured received power of the downlink signal. Calculating the propagation loss of the downlink signal, and the second propagation loss calculating means measures the reception power of the broadcast signal, and determines the transmission power of the broadcast signal and the measured reception power of the broadcast signal. Based on this, a propagation loss of the broadcast signal is calculated.
- the first propagation loss calculation means is based on the known base station maximum transmission power and the transmission power control information of the downlink signal notified from the first base station apparatus.
- the transmission power of the downlink signal is acquired, and the second propagation loss calculation means includes the known base station maximum transmission power and the transmission power control information of the notification signal notified from the second base station device, To obtain the transmission power of the notification signal.
- the first and second base station devices communicate with the mobile station device using an orthogonal frequency division multiple access scheme.
- a transmission power control method is a transmission power control method for performing handover from a first base station apparatus to a second base station apparatus, and is transmitted from the first base station apparatus.
- a step of calculating a propagation loss of a downlink signal, a step of calculating a propagation loss of a broadcast signal transmitted from the second base station device, a transmission power of the uplink signal to the first base station device, and the downlink And a step of controlling transmission power of an uplink signal to the second base station apparatus based on a difference between a propagation loss of the signal and a propagation loss of the broadcast signal.
- FIG. 1 is an overall configuration diagram of a mobile communication system according to an embodiment of the present invention. It is a functional block diagram of the mobile station which concerns on embodiment of this invention. It is a figure which shows the calculation method of ANCH transmission power. It is a figure which shows the other calculation method of ANCH transmission power. It is a figure which shows the transmission timing of ANCH. It is a figure which shows the positional relationship of the mobile station and base station at the time of a hand-over. It is a functional block diagram of the base station which concerns on embodiment of this invention. It is a figure which shows the hand-over sequence which concerns on embodiment of this invention. It is a figure which shows the call sequence of next generation PHS. It is a figure which shows the hand-over sequence of next generation PHS.
- FIG. 1 is an overall configuration diagram of a mobile communication system 10 according to an embodiment of the present invention.
- the mobile communication system 10 includes a plurality of mobile stations 12 (only one is shown here) and a plurality of base stations 14 (here, base stations communicating with the mobile station 12 ( Serving Base Station) 14-1 and a base station (Target Base Station) 14-2 that is the handover destination of the mobile station 12), and an ASN gateway 18 (ASN-GW: Access Service Network Gateway) It is configured.
- the base stations 14-1 and 14-2 and the ASN gateway 18 are connected to each other via the IP network 16.
- the base station 14 employs the TDMA / TDD system and the OFDMA system, and uses at least one communication channel formed by a combination of any of the time slots based on TDMA and any of the subchannels based on OFDMA. Communicate.
- the ASN gateway 18 is a known server computer that performs relay of inter-base station communication, authentication management, radio resource management, handover control, and the like.
- the mobile station transmits a timing correction channel (TCCH) (S318), and the handover destination base station transmits a signal control channel (downlink SCCH) (S326). Can be omitted, so that a fast handover can be realized.
- TCCH timing correction channel
- SCCH signal control channel
- FIG. 2 is a functional block diagram of the mobile station 12.
- the mobile station 12 includes an antenna 20, a radio communication unit 22, a downlink frame synchronization unit 24, a demodulation unit 26, a data detection unit 28, a storage unit 30, a propagation loss calculation unit 32, and a transmission power control unit 34.
- Some of these are configured by, for example, a CPU (Central Processing Unit) or a DSP (Digital Signal Processing).
- the antenna 20 receives a radio signal and outputs the received radio signal to the radio communication unit 22. Further, the antenna 20 transmits a radio signal supplied from the radio communication unit 22 to the base station 14. Reception and transmission of radio signals are switched in a time division manner in accordance with instructions from the radio communication unit 22.
- the wireless communication unit 22 includes a low noise amplifier, a power amplifier, a local oscillator, a mixer, and a filter.
- the radio communication unit 22 amplifies the radio signal input from the antenna 20 with a low noise amplifier, down-converts the radio signal to an intermediate frequency signal, and outputs the intermediate signal to the downlink frame synchronization unit 24. Further, the radio communication unit 22 up-converts the modulation signal input from the uplink frame synchronization unit 42 into a radio signal, amplifies it to a transmission output level with a power amplifier, and then supplies the signal to the antenna 20.
- the downlink frame synchronization unit 24 detects the correlation between the signal input from the wireless communication unit 22 and the known signal, and uses the timing at which the correlation greater than or equal to the predetermined value is detected as the reception timing of the downlink signal transmitted from the base station 14. To detect. Then, based on the detected reception timing of the downlink signal, the downlink frame synchronization unit 24 establishes downlink frame synchronization with the base station 14. Further, the downlink frame synchronization unit 24 measures the received power of the downlink signal transmitted from the base station 14.
- the demodulator 26 includes an A / D converter, a serial-parallel converter, an FFT (Fast Fourier Transform) arithmetic unit, and a parallel-serial converter.
- the demodulator 26 performs a removal of a guard interval (GI), A / D conversion, serial / parallel conversion, discrete Fourier transform, parallel / serial conversion, and the like on the signal input from the downlink frame synchronization unit 24 and continues. Get complex symbol sequence. The complex symbol sequence acquired in this way is output to the data detection unit 28.
- GI guard interval
- the data detection unit 28 detects a data bit sequence (reception data) corresponding to the symbol modulation method from the complex symbol sequence input from the demodulation unit 26, and outputs the detected reception data to an upper layer (not shown).
- the storage unit 30 is configured by, for example, a semiconductor memory element, and stores the reception timing of the downlink signal detected by the downlink frame synchronization unit 24, the reception power of the downlink signal measured by the downlink frame synchronization unit 24, and the like.
- the propagation loss calculation unit 32 calculates the propagation loss of the downlink signal (downlink common channel (CCH: Common Channel) or downlink individual channel (ICH: Individual Channel)) transmitted from the base station 14.
- the broadcast control channel (BCCH) is one of the downlink common channels (CCH).
- the propagation loss calculation unit 32 includes the known base station maximum transmission power PtMAX_BS, the transmission power control information ⁇ Pt_BS2 included in the broadcast control channel, the received power RSSI_BS2 of the broadcast control channel stored in the storage unit 30, Based on the above, the propagation loss LOSS_BS2 of the broadcast control channel is calculated.
- the transmission power control unit 34 controls the transmission power of the uplink signal for the base station 14. In particular, when the mobile station 12 performs a handover from the base station 14-1 to the base station 14-2, the transmission power control unit 34 determines that the received power of the ANCH at the handover destination base station 14-2 is the base station desired received power Z The transmission power of the ANCH is controlled to be equal to An ANCH PRU (single channel consisting of one communication channel) used for communication with the handover destination base station 14-2 sends a handover response transmitted from the communicating base station 14-1, as will be described later. Via the handover destination base station 14-2.
- An ANCH PRU single channel consisting of one communication channel
- the above-mentioned mobile station is set to the desired received power Z of the base station.
- the transmission power control unit 34 based on the known base station desired reception power Z and the propagation loss LOSS_BS2 calculated by the propagation loss calculation unit 32, transmits the ANCH transmission power to the handover destination base station 14-2.
- Pt_MS2 is calculated.
- the calculated transmission power Pt_MS2 is supplied to the modulation unit 40.
- FIG. 4 is a diagram illustrating another method for calculating the transmission power of the ANCH for the handover destination base station 14-2.
- the transmission power of the uplink signal to the base station 14-1 is previously set so that the reception power of the uplink signal (uplink CCH or uplink ICH) at the communicating base station 14-1 is equal to the base station desired reception power Z. This method is based on the premise that it is controlled.
- the propagation loss LOSS_BS1 calculated in this way can be regarded as a propagation loss between the mobile station 12 and the base station 14-1.
- the uplink signal transmission power Pt_MS1 for the base station 14-1 in communication is determined so that the reception power of the uplink signal at the base station 14-1 is equal to the base station desired reception power Z.
- the transmission power control unit 34 transmits the uplink signal transmission power Pt_MS1 to the communicating base station 14-1, the downlink signal transmission loss LOSS_BS1 transmitted from the communicating base station 14-1, and the handover destination. Based on the difference from the propagation loss LOSS_BS2 of the broadcast control channel transmitted from the base station 14-2, the ANCH transmission power Pt_MS2 for the handover destination base station 14-2 may be calculated.
- the timing correction amount calculation unit 36 transmits a downlink signal transmitted from the communicating base station 14-1.
- the timing difference between the reception timing of (downlink CCH or downlink ICH) and the reception timing of the broadcast control channel (BCCH) transmitted from the handover destination base station 14-2 is calculated as a timing correction amount ⁇ t.
- the timing correction amount ⁇ t is supplied to the upstream frame synchronization unit 42.
- the two reception timings used for calculating the timing correction amount ⁇ t are read from the storage unit 30.
- the time slot in which the communicating base station 14-1 transmits a downlink signal may be different from the time slot in which the handover destination base station 14-2 transmits a broadcast control channel.
- the timing correction amount calculation unit 36 sets a value obtained by further subtracting the interval between the time slots (a multiple of the time slot length) from the timing difference as the timing correction amount ⁇ t.
- the data generation unit 38 generates transmission data by adding header information or the like corresponding to the format of the transmission channel to a data bit string input from an upper layer (not shown).
- the generated transmission data is output to the modulation unit 40.
- the modulation unit 40 includes a serial-parallel converter, an IFFT (Inverse Fourier Transform) operation unit, a parallel-serial converter, and a D / A converter.
- the modulation unit 40 performs symbol mapping (assignment of amplitude and phase) on the transmission data input from the data generation unit 38 according to the modulation scheme, and obtains a complex symbol sequence.
- the modulation unit 40 divides the obtained complex symbol sequence into subcarrier components, and the transmission power of the uplink signal (uplink ANCH or the like) becomes the transmission power calculated by the transmission power control unit 34. To adjust the subcarrier component corresponding to the PRU allocated from. Then, the modulation unit 40 performs serial-parallel conversion, inverse discrete Fourier transform, parallel-serial conversion, D / A conversion, and the like on each carrier component of the adjusted complex symbol sequence to obtain a baseband OFDM signal. The baseband OFDM signal acquired in this way is output to the upstream frame synchronization unit 42 after a guard interval is added.
- the uplink frame synchronization unit 42 is calculated by the timing correction amount calculation unit 36 when the mobile station 12 performs a handover from the communicating base station 14-1 with established uplink frame synchronization to the base station 14-2. Based on the timing correction amount ⁇ t, the ANCH transmission timing to the handover destination base station 14-2 is corrected.
- the uplink frame synchronization unit 42 transmits the downlink signal (downlink CCH or downlink ICH) transmitted from the base station 14-1 with which the BCCH transmitted from the handover destination base station 14-2 is communicating.
- the ANCH signal is output to the radio communication unit 22 earlier by
- the frame synchronization unit 42 outputs an ANCH signal to the radio communication unit 22 later by ⁇ t than the transmission timing of the uplink signal (uplink CCH or uplink ICH) to the base station 14-1.
- the uplink frame synchronization unit 42 The ANCH transmission timing is corrected by further considering the interval between the time slots (a multiple of the time slot length).
- FIG. 7 is a functional block diagram of the base station 14.
- the base station 14 includes an antenna 50, a radio communication unit 52, a demodulation unit 54, a data detection unit 56, an IP interface unit 58, a communication channel control unit 60, a handover control unit 62, a data generation unit 64, And a modulation unit 66.
- Some of these are constituted by, for example, a CPU or a DSP.
- the antenna 50 receives a radio signal and outputs the received radio signal to the radio communication unit 52. Further, the antenna 50 transmits a radio signal supplied from the radio communication unit 52 to the mobile station 12. Note that reception and transmission of wireless signals are switched in a time-sharing manner in accordance with instructions from the wireless communication unit 52.
- the wireless communication unit 52 includes a low noise amplifier, a power amplifier, a local oscillator, a mixer, and a filter.
- the radio communication unit 52 amplifies the radio signal input from the antenna 50 with a low noise amplifier, down-converts the radio signal to an intermediate frequency signal, and outputs the signal to the demodulation unit 54.
- the wireless communication unit 52 up-converts the modulation signal input from the modulation unit 66 into a wireless signal, amplifies the signal to a transmission output level with a power amplifier, and then supplies the signal to the antenna 50.
- the demodulator 54 includes an A / D converter, a serial / parallel converter, an FFT operation unit, and a parallel / serial converter.
- the demodulator 54 performs guard interval removal, A / D conversion, serial-parallel conversion, discrete Fourier transform, parallel-serial conversion, and the like on the signal input from the wireless communication unit 52 to obtain a continuous complex symbol sequence.
- the complex symbol sequence acquired in this way is output to the data detection unit 56.
- the data detection unit 56 detects a data bit sequence (reception data) corresponding to the symbol modulation method from the complex symbol sequence input from the demodulation unit 54, and detects the detected reception data in the IP interface unit 58, the handover control unit 62, and the like. Output to.
- the IP interface unit 58 generates an IP packet by adding a predetermined IP header to the data input from the handover control unit 62 and the data generation unit 64, and transmits the IP packet to another base station 14 via the IP network 16. Or to the ASN gateway 18.
- the IP interface unit 58 receives IP packets transmitted from other base stations 14 and the ASN gateway 18 via the IP network 16, and uses the handover control unit 62 and the data generation unit for payload data included in the received IP packets. To the unit 64 and the like.
- the communication channel control unit 60 responds to a request from the mobile station 12 by using an ANCH PRU (single channel consisting of one communication channel) or an EXCH PRU (one or more communication channels) allocated to the mobile station 12. Channel) and the like, and the determined PRU is notified to the mobile station.
- an ANCH PRU single channel consisting of one communication channel
- EXCH PRU one or more communication channels allocated to the mobile station 12. Channel
- the handover control unit 62 uses the ANCH assigned to the mobile station 12 by the communication channel control unit 60.
- a handover request including the PRU is generated, and the handover request is transmitted to the handover destination base station 14-2 via the ASN gateway 18.
- the handover control unit 62 notifies the communication channel control unit 60 of a new ANCH PRU included in the handover response (Switching Response) returned from the handover destination base station 14-2 and moves the handover response.
- the data generator 64 is instructed to transmit to the station 12.
- the communication channel control unit 60 needs to ensure that the new ANCH PRU time slot notified from the handover control unit 62 and the EXCH PRU time slot allocated to the mobile station 12 do not overlap. Accordingly, the allocation of EXCH PRUs is changed. That is, the communication channel control unit 60 restricts the EXCH PRU allocated to the mobile station 12 to a time slot excluding the new ANCH PRU time slot notified from the handover control unit 62.
- the handover control unit 62 determines the ANCH PRU included in the handover request.
- the communication channel control unit 60 is notified.
- the communication channel control unit 60 determines one free PRU included in a time slot different from the time slot of the ANCH PRU notified from the handover control unit 62 as a new ANCH PRU.
- the handover control unit 62 generates a handover response including the new ANCH PRU determined by the communication channel control unit 60, and returns the handover response to the base station 14-1 via the ASN gateway 18.
- the data generation unit 64 adds the header information according to the format of the transmission channel to the data bit string from the IP interface unit 58 or the handover control unit 62, and generates transmission data.
- the generated transmission data is output to modulation section 66.
- the modulation unit 66 includes a serial-parallel converter, an IFFT calculation unit, a parallel-serial converter, and a D / A converter.
- the modulation unit 66 performs symbol mapping, serial / parallel conversion, inverse discrete Fourier transform, parallel / serial conversion, D / A conversion, and the like on the transmission data input from the data generation unit 64 to obtain a baseband OFDM signal. .
- the baseband OFDM signal acquired in this way is output to the wireless communication unit 52 after a guard interval is added.
- This handover is a soft handover in which the mobile station 12 performs communication simultaneously with the base station 14-1 with which the mobile station 12 is communicating and the base station 14-2 that is the handover destination. It is assumed that the mobile station 12 has already established uplink frame synchronization with the communicating base station 14-1. Further, the transmission power Pt_MS1 of the uplink signal (uplink CCH or uplink ICH) to the base station 14-1 has been controlled so that the reception power of the uplink signal at the base station 14-1 is equal to the base station desired reception power Z. To do.
- the base station 14 periodically transmits a broadcast control channel (BCCH) including its own base station ID and transmission power control information (S100).
- BCCH broadcast control channel
- the mobile station 12 uses the broadcast control channel with the highest received power among the broadcast control channels transmitted from each base station 14 (in this case, the broadcast control channel transmitted from the base station 14-2), based on the base station 14- 2.
- Downlink frame synchronization is established with S2 (S102).
- the mobile station 12 stores the reception timing and reception power of the broadcast control channel transmitted from the base station 14-2 in the storage unit 30.
- the mobile station 12 transmits a handover request to the base station 14-2 to the communicating base station 14-1 (S104).
- the base station 14-1 receives the handover request from the mobile station 12, the base station 14-1 generates a handover request including the ANCH PRU assigned to the mobile station 12 by the base station 14-1, and sends the handover request via the ASN gateway 18. Transmit to the handover destination base station 14-2 (S106, S108).
- the base station 14-2 that has received the handover request from the base station 14-1 exchanges a path registration request, a path registration response, authentication information, etc. with the ASN gateway 18 (S110), and then makes a handover request.
- One empty PRU included in a time slot different from the time slot of the included ANCH PRU is determined as a new ANCH PRU (S112).
- a handover response including the determined new ANCH PRU is transmitted to the base station 14-1 via the ASN gateway 18 (S114, S116).
- the base station 14-1 Upon receiving the handover response from the base station 14-2, the base station 14-1 transmits a handover response including the new ANCH PRU determined by the base station 14-2 to the mobile station 12 (S118).
- the base station 14-1 determines the time slot of the new ANCH PRU determined by the base station 14-2, the time slot of the EXCH PRU assigned to the mobile station 12 by the base station 14-1, The EXCH PRU assignment is changed as necessary so that the two do not overlap.
- the mobile station 12 When receiving the handover request from the communicating base station 14-1, the mobile station 12 acquires a new ANCH PRU from the handover response (S120). Next, the mobile station 12 includes the known base station maximum transmission power, the transmission power control information included in the broadcast control channel received in S100, and the received power of the broadcast control channel stored in the storage unit 30. Based on this, the propagation loss of the broadcast control channel, that is, the propagation loss between the mobile station 12 and the base station 14-2 is calculated. Then, based on the known desired reception power of the base station and the calculated propagation loss between the mobile station 12 and the base station 14-2, the transmission power of the ANCH to the handover destination base station 14-2 is calculated and corrected ( S122, S124).
- the mobile station 12 receives the downlink signal (downlink CCH or downlink ICH) received from the communicating base station 14-1 and the broadcast control channel received from the handover destination base station 14-2.
- the timing is read from the storage unit 30, and the timing difference is calculated as a timing correction amount (S126).
- uplink frame synchronization is established with the handover destination base station 14-2 by correcting the ANCH transmission timing based on the calculated timing correction amount (S128).
- the mobile station 12 uses the ANCH PRU acquired in S120 to transmit the uplink ANCH that requests the allocation of the EXCH PRU at the transmission power corrected in S124 and the transmission timing corrected in S128, to the handover destination base station. It is transmitted to 14-2 (S130).
- the base station 14-2 that has received the uplink ANCH from the mobile station 12 determines an EXCH PRU composed of one or more PRUs to be allocated to the mobile station 12 (S132), and transmits the downlink ANCH including the determined EXCH PRU to the mobile station. 12 (S134). In this way, the mobile station 12 receives the allocation of the ANCH PRU and the EXCH PRU from the handover destination base station 14-2.
- the base station 14-2 that has received the connection request confirms execution of the handover with the ASN gateway 18. From (S138), a connection response is returned to the mobile station 12 (S140). At this time, the ASN gateway 18 transmits a path deletion request to the base station 14-1 (S142), and releases the connection between the mobile station 12 and the base station 14-1 (S144).
- the present invention is not limited to the next-generation PHS employing the TDMA / TDD scheme and the OFDMA scheme, but the first and second base stations, and the mobile station that performs handover from the first base station to the second base station And can be widely applied to all mobile communication systems.
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Claims (10)
- 第1の基地局装置から第2の基地局装置にハンドオーバを行う移動局装置であって、
前記第2の基地局装置から送信される報知信号の伝搬損失を算出する伝搬損失算出手段と、
既知の基地局所望受信電力と前記伝搬損失算出手段により算出された伝搬損失とに基づいて、前記第2の基地局装置に対する上り信号の送信電力を制御する送信電力制御手段と、
を含むことを特徴とする移動局装置。 - 請求項1に記載の移動局装置において、
前記伝搬損失算出手段は、前記報知信号の受信電力を測定し、前記報知信号の送信電力と該測定された前記報知信号の受信電力とに基づいて、前記報知信号の伝搬損失を算出する、
ことを特徴とする移動局装置。 - 請求項1または2に記載の移動局装置において、
前記伝搬損失算出手段は、既知の基地局最大送信電力と前記第2の基地局装置から通知される前記報知信号の送信電力制御情報とに基づいて、前記報知信号の送信電力を取得する、
ことを特徴とする移動局装置。 - 請求項1に記載の移動局装置において、
前記第1および第2の基地局装置は、直交周波数分割多元接続方式により、前記移動局装置と通信を行う、
ことを特徴とする移動局装置。 - 第1の基地局装置から第2の基地局装置にハンドオーバを行う際の送信電力制御方法であって、
前記第2の基地局装置から送信される報知信号の伝搬損失を算出するステップと、
既知の基地局所望受信電力と前記報知信号の伝搬損失とに基づいて、前記第2の基地局装置に対する上り信号の送信電力を制御するステップと、
を含むことを特徴とする送信電力制御方法。 - 第1の基地局装置から第2の基地局装置にハンドオーバを行う移動局装置であって、
前記第1の基地局装置から送信される下り信号の伝搬損失を算出する第1の伝搬損失算出手段と、
前記第2の基地局装置から送信される報知信号の伝搬損失を算出する第2の伝搬損失算出手段と、
前記第1の基地局装置に対する上り信号の送信電力と、前記第1の伝搬損失算出手段により算出された伝搬損失と前記第2の伝搬損失算出手段により測定された伝搬損失との差と、に基づいて、前記第2の基地局装置に対する上り信号の送信電力を制御する送信電力制御手段と、
を含むことを特徴とする移動局装置。 - 請求項6に記載の移動局装置において、
前記第1の伝搬損失算出手段は、前記下り信号の受信電力を測定し、前記下り信号の送信電力と該測定された前記下り信号の受信電力とに基づいて、前記下り信号の伝搬損失を算出し、
前記第2の伝搬損失算出手段は、前記報知信号の受信電力を測定し、前記報知信号の送信電力と該測定された前記報知信号の受信電力とに基づいて、前記報知信号の伝搬損失を算出する、
ことを特徴とする移動局装置。 - 請求項6または7に記載の移動局装置において、
前記第1の伝搬損失算出手段は、既知の基地局最大送信電力と前記第1の基地局装置から通知される前記下り信号の送信電力制御情報とに基づいて、前記下り信号の送信電力を取得し、
前記第2の伝搬損失算出手段は、前記既知の基地局最大送信電力と前記第2の基地局装置から通知される前記報知信号の送信電力制御情報とに基づいて、前記報知信号の送信電力を取得する、
ことを特徴とする移動局装置。 - 請求項6に記載の移動局装置において、
前記第1および第2の基地局装置は、直交周波数分割多元接続方式により、前記移動局装置と通信を行う、
ことを特徴とする移動局装置。 - 第1の基地局装置から第2の基地局装置にハンドオーバを行う際の送信電力制御方法であって、
前記第1の基地局装置から送信される下り信号の伝搬損失を算出するステップと、
前記第2の基地局装置から送信される報知信号の伝搬損失を算出するステップと、
前記第1の基地局装置に対する上り信号の送信電力と、前記下り信号の伝搬損失と前記報知信号の伝搬損失との差と、に基づいて、前記第2の基地局装置に対する上り信号の送信電力を制御するステップと、
を含むことを特徴とする送信電力制御方法。
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WO2016188409A1 (zh) * | 2015-05-26 | 2016-12-01 | 苏州阿福机器人有限公司 | 手执示教机器人及机器人手执示教方法 |
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US8787310B2 (en) | 2014-07-22 |
US20110038351A1 (en) | 2011-02-17 |
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