CN104333868A - Relay device and method for wireless communication - Google Patents
Relay device and method for wireless communication Download PDFInfo
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- CN104333868A CN104333868A CN201410642184.1A CN201410642184A CN104333868A CN 104333868 A CN104333868 A CN 104333868A CN 201410642184 A CN201410642184 A CN 201410642184A CN 104333868 A CN104333868 A CN 104333868A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W16/00—Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
- H04W16/24—Cell structures
- H04W16/26—Cell enhancers or enhancement, e.g. for tunnels, building shadow
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/14—Relay systems
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/0001—Systems modifying transmission characteristics according to link quality, e.g. power backoff
- H04L1/0009—Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the channel coding
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Abstract
The invention provides a relay device for wireless communication and a relay method for wireless communication, and realizes multi-jump multi-point netlike relay among wireless communication nodes. The relay device comprises a system control module, a data selection module, a baseband signal transmission module, a timing frequency deviation and carrier frequency deviation correction module, an up conversion module, a receiving and transmitting radio frequency switching module, a down conversion module, a timing frequency deviation and carrier frequency deviation estimation module and a baseband signal receiving module. According to the device, a route is not required, the relay is improved from a multi-jump multi-point linear relay into the multi-jump multi-point netlike relay, and other relay circuits in the relay network work normally when any node in the relay network is disconnected and off-line, so that the relay effect is not affected.
Description
Technical field
The present invention relates to the relaying technique in radio communication, be specifically related to the netted relay of multi-hop multiple spot and the method for a kind of predistortion carrier wave frequency deviation and timing frequency deviation.
Background technology
The contradiction of the High Data Rate bandwidth sum high reliability that cordless communication network exists, should ensure that user has sufficiently high data rate bandwidth, meet the requirement of transmission range and coverage effect again.Therefore, development cordless communication network needs the various technological means of integrated use, take different core technology means for different application demand, solve zones of different, different user group to the different demands of bandwidth and business, reach high reliability and the fail safe of cordless communication network.
Relaying is as one of Main Means expanding communication coverage.Wireless communication system is made up of multiple terminal node networking, the impact of the composite factor such as mutual interference and landform between the change of the random movement of terminal, the startup and shutdown at any time of node, wireless transmitting device transmitted power, wireless channel, the network topology structure that terminal room is formed by wireless channel may change at any time, and change mode and speed be all uncertain.Traditional relaying technique needs to carry out route to select trunk, every one-level all only has a node to carry out relaying, the quality that the movement of arbitrary node in trunk, broken string all can affect relaying is with connective, thus cause the search of repeatability and upgrade trunk, reduce reliability and the valid data bandwidth of system.
It is much lower that the physical characteristic of wireless channel itself determines junction network bandwidth ratio wire message way, and the factors such as collision that sharing wireless channel produces, signal attenuation, noise jamming and channel disturbance of competing make the actual bandwidth of mobile terminal be less than theoretical value.Due to transmitting power and the limited coverage area of terminal, when terminal will communicate with the terminal outside coverage, need to utilize intermediate node to carry out relay forwarding.Traditional wireless communication radio station does not generally possess relay function, and the Radio Station of existing relay function is the multi-hop single-point wire relaying of a network layer, selects route lines to carry out relaying by network layer protocol.Meanwhile, junction network generally has Controlling vertex, and for controlling selection mode and the routing mode of via node, when Controlling vertex breaks down or leave network, system can cannot normally be run.
Summary of the invention
Least for one or more in solving the problem, the present invention proposes a kind of trunking method for radio communication, by process overall planning, automatically judgement, multiple spot relayings such as the reception of data message, transmitting, relayings, realize the propagation of wireless signal, covering and relaying, complete the error free transport of the data messages such as voice, data, video.Solve a difficult problem for current wireless communication field limited transmission distance and coverage effect difference, and it is strong to have antijamming capability, substantially increases the wireless access scope in a specific region.The invention allows for a kind of relay for radio communication, Multipoint synchronous relaying can be completed by this device and form junction network.Different from the route relaying in general networking, the multihop routing of the junction network that the present invention proposes is completed by ordinary node collaborate, instead of to be completed by special routing device, all nodes directly can select whether participate in relay forwarding according to bottom channel transfer characteristic.Carrier wave frequency deviation and timing frequency deviation are corrected by embodiment of the present invention method in advance, arbitrary node can receive the same signal processing and forward from multiple node simultaneously, these signals forwarded from different node are carried out signal merging, the demodulation raw information of maximum possible.Therefore there is larger transmission range and the transmission reliability of Geng Gao.
In a preferred embodiment of the invention, the present invention proposes a kind of trunking method for radio communication, it is characterized in that it comprises the following steps:
1) data message carries out upconverting to radio-frequency carrier and getting on after baseband signal launches process by transmitting node, launches at time slot 1;
2) be down-converted to base band after the radiofrequency signal that via node receives from transmitting node or higher level's via node, carry out baseband signal and receive restoring data information after process, and carry out Nonlinear Transformation in Frequency Offset Estimation and timing frequency deviation is estimated, carry out the judgement of whether relaying;
3) judgement needs the node of relaying to carry out after baseband signal launches process, correcting carrier wave frequency deviation and timing frequency deviation in advance to the data message of required relaying, and upconverts to radio-frequency carrier and get on, at next slot transmission;
4) be down-converted to base band after the radiofrequency signal of receiving node reception from one or more via node, carry out baseband signal and receive the rear restoring data information of process.
The decision method of the whether relaying described in the above-mentioned trunking method for radio communication is: when the data message of reduction is errorless and received signal quality just carries out relaying after reaching preset standard.
The errorless criterion of data message described in the above-mentioned trunking method for radio communication is: whether the iterations of CRC check whether success, decoding reaches maximum iteration time.
Received signal quality described in the above-mentioned trunking method for radio communication is one or more combination of Received signal strength field intensity, decoding iteration number of times and synchronized tracking precision.
Carrier frequency bias estimation described in the above-mentioned trunking method for radio communication is the pilot tone estimation technique or frame synchronization sequence Correlation Estimation Method, wherein, namely the pilot tone estimation technique obtains Nonlinear Transformation in Frequency Offset Estimation in the incremental change of the phase deviation at pilot tone place statistics divided by pilot tone incremental number; After namely frame synchronization sequence Correlation Estimation Method utilizes local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, Nonlinear Transformation in Frequency Offset Estimation can be obtained by the phase deviation of adjacent two relevant peaks divided by the distance of adjacent two relevant peaks.
Timing frequency deviation method of estimation described in the above-mentioned trunking method for radio communication is the pilot tone estimation technique or frame synchronization sequence Correlation Estimation Method, wherein, namely the pilot tone estimation technique obtains timing frequency deviation estimation in the incremental change of the time migration at pilot tone place statistics divided by pilot tone incremental number; After namely frame synchronization sequence Correlation Estimation Method utilizes local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, timing frequency deviation can be obtained by the time migration of adjacent two relevant peaks divided by the distance of adjacent two relevant peaks and estimate.
Carrier wave frequency deviation antidote described in the above-mentioned trunking method for radio communication is conjugation multiplication.
Timing frequency deviation antidote described in the above-mentioned trunking method for radio communication is filtering interpolation, realize by FIR interpolation filter, IIR interpolation filter realize, be fourier transformed into frequency domain after by carrying out Fourier inversion realization again after filtering frequency response multiplication.
The jumping figure of the via node described in the above-mentioned trunking method for radio communication can be comprise 1 any positive integer.
Baseband signal described in the above-mentioned trunking method for radio communication is launched process and is comprised: coding, intertexture, pilots insertion, signal framing, filtering are shaping.
Wherein, the execution mode of coding can be one or more the cascading in convolution code, Reed-solomon (RS) code, LDPC code, Turbo code;
Wherein, the execution mode of intertexture can be the one of convolutional interleave, block interleaving;
Wherein, the execution mode of pilots insertion can be one or both combination of scattered pilot, continuous pilot;
Wherein, the execution mode of signal framing can be by before Frame or the mode inserting frame synchronization sequence below realize;
Wherein, the execution mode that filtering is shaped can be the one of raised cosine roll off filtering, square root raised cosine filter, matched filtering, butterworth filter, Chebyshev filtering.
Baseband signal described in the above-mentioned trunking method for radio communication receives process and comprises: filtering, carrier synchronization, Timing Synchronization, frame synchronization, channel estimating, channel equalization, deinterleaving, decoding.
Wherein, the execution mode of coding can be one or more the cascading in convolution code, Reed-solomon (RS) code, LDPC code, Turbo code;
Wherein, the execution mode of intertexture can be the one of convolutional interleave, block interleaving;
Wherein, the execution mode of pilots insertion can be one or both combination of scattered pilot, continuous pilot;
Wherein, the execution mode of signal framing can be by before Frame or the mode inserting frame synchronization sequence below realize;
Wherein, the execution mode that filtering is shaped can be the one of raised cosine roll off filtering, square root raised cosine filter, matched filtering, butterworth filter, Chebyshev filtering.
Step 2 in above-described embodiment 1), step 4) described in baseband signal receive process comprise: filtering, carrier synchronization, Timing Synchronization, frame synchronization, channel estimating, channel equalization, deinterleaving, decoding.
Wherein, the execution mode of filtering can be the one of raised cosine roll off filtering, square root raised cosine filter, matched filtering, butterworth filter, Chebyshev filtering;
Wherein, the execution mode of carrier synchronization is catching of pilot frequency carrier wave information and follows the tracks of;
Wherein, the execution mode of Timing Synchronization is catching of pilot tone timing information and follows the tracks of;
Wherein, the execution mode of frame synchronization is catching of frame synchronization sequence relevant peaks and follows the tracks of;
Wherein, the execution mode of channel estimating can be channel estimation in frequency domain, time domain channel is estimated, coherent channel is estimated, the one of incoherent channel estimating;
Wherein, the execution mode of channel equalization can be the one of frequency domain equalization, time domain equalization, feedback equalization;
Wherein, the execution mode of deinterleaving can be the one of convolution de-interleaving, block deinterleaving;
Wherein, the execution mode of decoding can be one or more the cascading in convolution decoder, Reed-solomon (RS) decoding, LDPC decoding, Turbo decoding.
The operation principle of the trunking method that the present invention proposes as shown in Figure 1.Terminal 0 attempts to communicate with terminal 4, and system has divided 4 time slots altogether.Terminal 0 uses time slot 1 to carry out Signal transmissions; The first order of relaying is in terminal 0 terminal 1_1 nearby, terminal 1_2 and terminal 1_3, after terminal 1_1, terminal 1_2 and terminal 1_3 receive the data message of self terminal 0 transmitting, after the relay decision method proposed by the present invention is adjudicated and is reached relay condition, after the trunking method proposed by the present invention carries out carrier wave frequency deviation and timing frequency deviation predistortion, time slot 2 is used to carry out signal relay transmission; Terminal 2_1, terminal 2_2, terminal 2_3 and terminal 2_4 are in the second level of relaying, after terminal 2_1 receives the data message of self terminal 1_1 and terminal 1_2 relaying, after the relay decision method proposed by the present invention is adjudicated and is reached relay condition, after the trunking method proposed by the present invention carries out carrier wave frequency deviation and timing frequency deviation predistortion, time slot 3 is used to carry out signal relay transmission; After terminal 2_2 receives the data message of self terminal 1_1, terminal 1_2 and terminal 1_3 relaying, after the relay decision method proposed by the present invention is adjudicated and is reached relay condition, after the trunking method proposed by the present invention carries out carrier wave frequency deviation and timing frequency deviation predistortion, time slot 3 is used to carry out signal relay transmission; After terminal 2_3 receives the data message from terminal 1_3 relaying, after the relay decision method proposed by the present invention is adjudicated and is reached relay condition, after the trunking method proposed by the present invention carries out carrier wave frequency deviation and timing frequency deviation predistortion, time slot 3 is used to carry out signal relay transmission; After terminal 2_4 receives the data message of self terminal 1_3 relaying, after the relay decision method proposed by the present invention is adjudicated and is reached relay condition, after the trunking method proposed by the present invention carries out carrier wave frequency deviation and timing frequency deviation predistortion, time slot 3 is used to carry out signal relay transmission; Terminal 3_1 and terminal 3_2 is in the third level of relaying, after terminal 3_1 receives the data message of self terminal 2_1 and terminal 2_2 relaying, after the relay decision method proposed by the present invention is adjudicated and is reached relay condition, after the trunking method proposed by the present invention carries out carrier wave frequency deviation and timing frequency deviation predistortion, time slot 4 is used to carry out signal relay transmission; After terminal 3_2 receives the data message of self terminal 2_1, terminal 2_2, terminal 2_3 and terminal 2_4 relaying, after the relay decision method proposed by the present invention is adjudicated and is reached relay condition, after the trunking method proposed by the present invention carries out carrier wave frequency deviation and timing frequency deviation predistortion, time slot 4 is used to carry out signal relay transmission; After terminal 4 receives the data message of self terminal 3_1 and terminal 3_2 relaying, namely complete data message from terminal 0 to the transmission of terminal 4.Data message from terminal 4 to the transmission of terminal 0 and above-mentioned data message similar to the transmission of terminal 4 from terminal 0.Like this, the trunking method utilizing the present invention to propose completes the multi-hop multiple spot relaying of terminal 0 and terminal 4, system continues on circuit in each stage has 1 to participate in relaying to multiple via node, and because via node has carried out the predistortion of carrier wave frequency deviation and timing frequency deviation before forwarding data information, can not interference be produced at the signal of multiple relaying institutes relaying of same one-level, the enhancing of signal can be obtained on the contrary and can expand the coverage area.Arbitrary node in junction network leave the relaying quality that can not affect on other trunks, the trunking method that the present invention is proposed has better reliability and larger coverage.
Traditional trunking method needs route, and operation principle as shown in Figures 2 and 3.The communication line that in figure, represented by dotted arrows route may be selected, solid line represents the communication line of route actual selection.In fig. 2, routing termination 1_3 as the via node of the third level, thus completes the trunking traffic of terminal 0 and terminal 4 as the via node of the second level, terminal 3_2 as the via node of the first order, terminal 2_3.Every one-level of tradition trunking method all only has a node, is the multi-hop single-point relay system of a wire.If now terminal 1_3 leaves network, route will reselect trunk, the trunk of new selection as shown in Figure 3, routing termination 1_1 as the via node of the third level, thus completes the trunking traffic of terminal 0 and terminal 4 as the via node of the second level, terminal 3_1 as the via node of the first order, terminal 2_2.As can be seen here, tradition trunking method is the wire junction network of a multi-hop single-point, the quality that the movement of arbitrary node in trunk, broken string all can affect relaying with connective, thus cause the search of repeatability and upgrades trunk, reduces reliability and the valid data bandwidth of system.The trunking method that the present invention proposes defines a kind of netted junction network of multi-hop multiple spot, compared with the wire trunking scheme of traditional multi-hop single-point, have stability and reliability high, without the need to the advantage of route, can ensure the continuity of communication, reliability and high efficiency.In relay processes, arbitrary node can receive the same signal processing and forward from multiple node simultaneously, these signals forwarded from different node is carried out signal merging, the demodulation raw information of maximum possible.As shown in Figure 1, terminal 2_1 have received from the identical signal of whole 1_1 with the terminal 0 that terminal 1_2 forwards, correct and timing frequency deviation rectification because terminal 1_1 and terminal 1_2 has carried out carrier wave frequency deviation when forwarding, terminal 2_1 merges it, interference process is converted into energy supposition, therefore there is larger transmission range and the transmission reliability of Geng Gao.The trunking scheme of initiative of the present invention does not need route, multiple node adjudicates whether start forwarding automatically, relaying is promoted to the netted relaying of multi-hop multiple spot by multi-hop single-point wire relaying, when in junction network there is broken string off-grid in arbitrary node, other trunk in junction network normally works, and makes relaying effect unaffected.
The present invention proposes a kind of relay for radio communication, it contains:
System control module: it is connected with data selecting module, provides data selection control signal to data selecting module, for the selection of control data information; It is connected with transceiving radio frequency switch module, and provide transmitting-receiving control signal to transceiving radio frequency switch module, the transmitting-receiving carrying out radiofrequency signal controls; It is connected with timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, obtains timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation; It is connected with baseband signal receiver module, obtains field intensity and iterations, carries out relay decision, generates predistortion control signal; It is connected with timing frequency deviation and carrier wave frequency deviation rectification module, provides predistortion control signal to timing frequency deviation and carrier wave frequency deviation rectification module, for controlling the predistortion of timing frequency deviation and carrier wave frequency deviation;
Data selecting module: it is connected with system control module, baseband signal receiver module, baseband signal transmitter module, select one of to export, as the data message giving baseband signal transmitter module from the data message input of outside and the data message from baseband signal receiver module according to data selection control signal; When system is in general modfel, select the data message from outside to input, when system is in repeater mode, select the data message from baseband signal receiver module to export;
Baseband transmission module, it is connected with data selecting module, timing frequency deviation and carrier wave frequency deviation rectification module, is carried out by the data message exported giving timing frequency deviation and carrier wave frequency deviation rectification module after baseband signal launches process from data selecting module;
Timing frequency deviation and carrier wave frequency deviation rectification module: it is connected with baseband signal transmitter module, system control module, up-converter module, the predistortion control signal provided according to system control module gives up-converter module after carrying out the rectification of timing frequency deviation and carrier wave frequency deviation to the base band transmit exported from baseband signal transmitter module;
Up-converter module: it with timing frequency deviation and carrier wave frequency deviation rectification module, radio-frequency switch module be connected, the base band transmit after timing frequency deviation and the process of carrier wave frequency deviation rectification module is carried out upconverting to radio frequency, and gives radio-frequency switch module;
Radio-frequency switch module: it is connected with up-converter module, down conversion module, system control module, according to the transmitting-receiving control signal that system control module provides, carry out radio-frequency (RF) switch control, when receiving and dispatching control signal and being in emission state, the radiofrequency signal that up-converter module exports is delivered on radio-frequency carrier, when receiving and dispatching control signal and being in accepting state, give down conversion module by the radiofrequency signal on radio-frequency carrier;
Down conversion module: it is connected with radio-frequency switch module, timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, baseband signal receiver module, radiofrequency signal is obtained from radio-frequency switch module, export baseband receiving signals after carrying out down-converted, and give timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, baseband signal receiver module;
Timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module: it is connected with down conversion module, system control module, after down conversion module obtains baseband receiving signals, carry out timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation, and give system control module by estimated timing frequency deviation and carrier wave frequency deviation;
Baseband signal receiver module: it is connected with down conversion module, data selecting module, system control module, baseband signal reception process is carried out after down conversion module obtains baseband receiving signals, data selecting module is given by the data message obtained after process, export simultaneously, give system control module by the field intensity obtained after process and iterations information.
Baseband signal transmitter module described in above-mentioned relay apparatus comprises coding module, interleaving block, pilots insertion module, signal framing module, filtering forming module, as shown in Figure 6.
Wherein, the execution mode of coding module can be one or more the cascading in convolution code module, Reed-solomon (RS) code module, LDPC code module, Turbo code module;
Wherein, the execution mode of interleaving block can be the one of convolutional interleave module, block interleaving module;
Wherein, the execution mode of pilots insertion module can be one or both combination of scattered pilot module, continuous pilot module;
Wherein, the execution mode of signal framing module can be by before Frame or the module inserting frame synchronization sequence below realize;
Wherein, the execution mode of filtering shaping module can be the one of raised cosine roll off filtration module, square root raised cosine filter module, matched filtering module, butterworth filter module, Chebyshev filtration module.
Baseband signal receiver module described in above-mentioned relay apparatus comprises filtration module, carrier synchronization module, SNR detection module, frame synchronization module, channel estimation module, channel equalization module, de-interleaving block, decoder module, as shown in Figure 7.
Wherein, the execution mode of filtration module can be the one of raised cosine roll off filtration module, square root raised cosine filter module, matched filtering module, butterworth filter module, Chebyshev filtration module.
Wherein, the execution mode of carrier synchronization module is catching of pilot frequency carrier wave information and tracking module.
Wherein, the execution mode of SNR detection module is catching of pilot tone timing information and tracking module.
Wherein, the execution mode of frame synchronization module is catching of frame synchronization sequence relevant peaks and tracking module.
Wherein, the execution mode of channel estimation module can be the one of channel estimation in frequency domain module, time domain channel estimation module, coherent channel estimation module, incoherent channel estimation module.
Wherein, the execution mode of channel equalization module can be the one of frequency domain equalization module, time domain equalization module, feedback equalization module.
Wherein, the execution mode of de-interleaving block can be the one of convolution de-interleaving module, block de-interleaving block.
Wherein, the execution mode of decoder module can be one or more the cascading in convolution decoder module, Reed-solomon (RS) decoder module, LDPC decoder module, Turbo decoder module.
Timing frequency deviation described in above-mentioned relay apparatus and carrier wave frequency deviation rectification module comprise timing frequency deviation rectification module and carrier wave frequency deviation rectification module, wherein, timing frequency deviation rectification module is filtering interpolation module, can be realized by FIR interpolation filtering module, also can be realized by IIR interpolation filtering module, can also be realized by the module of carrying out Fourier inversion after filtering frequency response multiplication again after being fourier transformed into frequency domain.
Timing frequency deviation described in above-mentioned relay apparatus and carrier wave frequency deviation rectification module comprise timing frequency deviation rectification module and carrier wave frequency deviation rectification module, and wherein, carrier wave frequency deviation rectification module is conjugation multiplier module.
Timing frequency deviation described in above-mentioned relay apparatus and Nonlinear Transformation in Frequency Offset Estimation module comprise timing frequency deviation estimation module and Nonlinear Transformation in Frequency Offset Estimation module, and wherein, Nonlinear Transformation in Frequency Offset Estimation module is pilot tone estimation module or frame synchronization sequence correlation estimation module.Pilot tone estimation module, the incremental change of the phase deviation namely at pilot tone place adds up the module divided by pilot tone incremental number; Frame synchronization sequence correlation estimation module, after namely utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, by the phase deviation of adjacent two relevant peaks module divided by adjacent two relevant peaks distances.
Timing frequency deviation described in above-mentioned relay apparatus and Nonlinear Transformation in Frequency Offset Estimation module comprise timing frequency deviation estimation module and Nonlinear Transformation in Frequency Offset Estimation module, and wherein, timing frequency deviation estimation module is pilot tone estimation module or frame synchronization sequence correlation estimation module.Pilot tone estimation module, the incremental change of the time migration namely at pilot tone place adds up the module divided by pilot tone incremental number; Frame synchronization sequence correlation estimation module, after namely utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, by the time migration of adjacent two relevant peaks module divided by adjacent two relevant peaks distances.
System control module described in above-mentioned relay apparatus comprises relay decision module, and this relay decision module comprises the errorless decision device of data message and received signal quality decision device.
The errorless decision device of data message described in above-mentioned relay apparatus comprises the one in CRC check decision device or decoding iteration number decision device.
Received signal quality decision device described in above-mentioned relay apparatus comprises one or more the cascading in Received signal strength field intensity decision device, decoding iteration number of times decision device and synchronized tracking precision decision device.
A kind of relay for radio communication proposed based on the present invention can complete Multipoint synchronous relaying and form junction network.In this junction network, due to the impact of the composite factor such as mutual interference and landform between the change of the random movement of user terminal, the startup and shutdown at any time of node, wireless transmitting device transmitted power, wireless channel, the network topology structure that terminal room is formed by wireless channel may change at any time, and change mode and speed be all uncertain.A kind of relay for radio communication that the present invention proposes does not need route, multiple node adjudicates whether start forwarding automatically, relaying is promoted to the netted relaying of multi-hop multiple spot by multi-hop single-point wire relaying, when in junction network there is broken string off-grid in arbitrary node, other trunk in junction network normally works, and makes relaying effect unaffected.The junction network that the relay that the present invention proposes is formed has self-organization, and have the network topology structure of dynamic change, do not have strict control centre in network, the status of all nodes is equality, is a kind of peer to peer network.Node can add at any time and leave network, and the fault of any node all can not affect the operation of whole network, has very strong survivability.
Accompanying drawing explanation
Fig. 1 is the trunking method schematic diagram for radio communication of the present invention;
Fig. 2 is a kind of repeated link schematic diagram of traditional relay system;
Fig. 3 is the another kind of repeated link schematic diagram of traditional relay system;
The repeated link schematic diagram that Fig. 4 uses for the embodiment of the present invention 1;
Fig. 5 is the relay schematic diagram for radio communication of the present invention;
Fig. 6 is baseband signal transmitter module schematic diagram of the present invention;
Fig. 7 is baseband signal receiver module schematic diagram of the present invention.
Embodiment
A kind of trunking method for radio communication that the present invention proposes and device, be now described as follows in conjunction with the accompanying drawings and embodiments.As shown in Figure 1, the schematic diagram of the relay for radio communication that the present invention proposes as shown in Figure 5 for the schematic diagram of the trunking method for radio communication that the present invention proposes.
Embodiment 1
System has 2 time slots, 1 and jumps relaying, 4 communication terminals, as shown in Figure 4.The trunking traffic of terminal 0 and terminal 2 is completed by following steps:
1) data message carries out upconverting to radio-frequency carrier and getting on after baseband signal launches process by terminal 0, launches at time slot 1;
2) terminal 1_1 terminal 1_2 is down-converted to base band after receiving the radiofrequency signal of self terminal 0, carries out baseband signal and receives restoring data information after process, and carries out Nonlinear Transformation in Frequency Offset Estimation and timing frequency deviation and estimate, carries out the judgement of whether relaying;
3) terminal 1_1 and terminal 1_2 judgement needs relaying, carries out after baseband signal launches process, correcting carrier wave frequency deviation and timing frequency deviation in advance to the data message of required relaying, and upconverts to radio-frequency carrier and get on, and launches at time slot 2;
4) terminal 2 is down-converted to base band after receiving the radiofrequency signal of self terminal 1_1 and terminal 1_2, carries out baseband signal and receives the rear restoring data information of process.
Step 2 in above-described embodiment 1) described in decision method be: when the data message of reduction is errorless and received signal quality just carries out relaying after reaching preset standard.Received signal quality is one or more combination of Received signal strength field intensity, decoding iteration number of times and synchronized tracking precision.
The errorless detection mode of above-mentioned data message can be:
Execution mode one: whether successfully judged by CRC check, CRC check success then illustrates that data message is errorless, and CRC check failure then illustrates that data message is wrong;
Execution mode two: whether reach maximum iteration time to judge by the iterations of decoding, then illustrate that when decoding iteration number does not reach maximum iteration time data message is errorless, then illustrate that when decoding iteration number reaches maximum iteration time data message is wrong.
The execution mode of above-mentioned received signal quality preset standard can be:
Execution mode one: Received signal strength field intensity is not less than-95dBm and iterations is not more than 35% of maximum iteration time and synchronized tracking precision reaches error is less than 2%;
Execution mode two: Received signal strength field intensity is greater than-87dBm and iterations is less than 1/2 of maximum iteration time and synchronized tracking precision reaches error is not more than 9 ‰;
Execution mode three: Received signal strength field intensity is not less than-73dBm and iterations is not more than 1/3 of maximum iteration time and synchronized tracking precision reaches error is less than 2 ‰;
Execution mode four: Received signal strength field intensity is not less than-65dBm;
Execution mode five: iterations is not more than 40% of maximum iteration time;
Execution mode six: synchronized tracking precision reaches error and is less than 6 ‰;
Execution mode seven: Received signal strength field intensity is greater than-81dBm and iterations is less than 1/2 of maximum iteration time;
Execution mode eight: Received signal strength field intensity is greater than-86dBm, synchronized tracking precision reaches error and is not more than 5 ‰;
Execution mode nine: iterations is less than 1/3 of maximum iteration time and synchronized tracking precision reaches error is not more than 0.1 ‰.
The various threshold value settings of above-mentioned received signal quality preset standard and various compound mode are all contents that the present invention protects.
Step 2 in above-described embodiment 1) described in the execution mode of carrier frequency bias estimation can be:
Execution mode one: the pilot tone estimation technique, the incremental change statistics of the phase deviation namely at pilot tone place obtains Nonlinear Transformation in Frequency Offset Estimation divided by pilot tone incremental number;
Execution mode two: frame synchronization sequence Correlation Estimation Method, namely, after utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, Nonlinear Transformation in Frequency Offset Estimation can be obtained by the phase deviation of adjacent two relevant peaks divided by the distance of adjacent two relevant peaks.
Step 2 in above-described embodiment 1) described in the execution mode of timing frequency deviation method of estimation can be:
Execution mode one: the pilot tone estimation technique, the time deviation amount namely at pilot tone place obtains timing frequency deviation divided by pilot tone incremental number and estimates;
Execution mode two: frame synchronization sequence Correlation Estimation Method, namely, after utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, timing frequency deviation can be obtained by the time migration of adjacent two relevant peaks divided by the distance of adjacent two relevant peaks and estimate.
Step 3 in above-described embodiment 1) described in carrier wave frequency deviation antidote be conjugation multiplication, namely carry out conjugation multiplication with estimated the carrier wave frequency deviation phase shift sequence formed and the signal launched.
Step 3 in above-described embodiment 1) described in timing frequency deviation antidote be filtering interpolation, its execution mode can be:
Execution mode one: realized by FIR interpolation filter;
Execution mode two: realized by IIR interpolation filter;
Execution mode three: by after being fourier transformed into frequency domain by carrying out Fourier inversion realization again after filtering frequency response multiplication.
Step 1 in above-described embodiment 1), step 3) described in baseband signal launch process and comprise: coding, intertexture, pilots insertion, signal framing, filtering are shaping.
Wherein, the execution mode of coding can be one or more the cascading in convolution code, Reed-solomon (RS) code, LDPC code, Turbo code;
Wherein, the execution mode of intertexture can be the one of convolutional interleave, block interleaving;
Wherein, the execution mode of pilots insertion can be one or both combination of scattered pilot, continuous pilot;
Wherein, the execution mode of signal framing can be by before Frame or the mode inserting frame synchronization sequence below realize;
Wherein, the execution mode that filtering is shaped can be the one of raised cosine roll off filtering, square root raised cosine filter, matched filtering, butterworth filter, Chebyshev filtering.
Step 2 in above-described embodiment 1), step 4) described in baseband signal receive process comprise: filtering, carrier synchronization, Timing Synchronization, frame synchronization, channel estimating, channel equalization, deinterleaving, decoding.
Wherein, the execution mode of filtering can be the one of raised cosine roll off filtering, square root raised cosine filter, matched filtering, butterworth filter, Chebyshev filtering;
Wherein, the execution mode of carrier synchronization is catching of pilot frequency carrier wave information and follows the tracks of;
Wherein, the execution mode of Timing Synchronization is catching of pilot tone timing information and follows the tracks of;
Wherein, the execution mode of frame synchronization is catching of frame synchronization sequence relevant peaks and follows the tracks of;
Wherein, the execution mode of channel estimating can be channel estimation in frequency domain, time domain channel is estimated, coherent channel is estimated, the one of incoherent channel estimating;
Wherein, the execution mode of channel equalization can be the one of frequency domain equalization, time domain equalization, feedback equalization;
Wherein, the execution mode of deinterleaving can be the one of convolution de-interleaving, block deinterleaving;
Wherein, the execution mode of decoding can be one or more the cascading in convolution decoder, Reed-solomon (RS) decoding, LDPC decoding, Turbo decoding.
In embodiment 1, number of timeslots can also be the positive integers arbitrarily such as 3,4,5,6,8,16, and terminal quantity can also be the positive integers arbitrarily such as 3,5,6,8,12,16, and relaying jumping figure can also be the positive integers arbitrarily such as 2,3,4,5,6,8.Any selection of number of timeslots, terminal quantity, relaying jumping figure is all contents that the present invention protects.
Embodiment 2
System has 4 time slots, 3 and jumps relaying, 11 communication terminals, as shown in Figure 1.The trunking traffic of terminal 0 and terminal 4 is completed by following steps:
1) data message carries out upconverting to radio-frequency carrier and getting on after baseband signal launches process by terminal 0, launches at time slot 1;
2) first order relaying: terminal 1_1, terminal 1_2 and terminal 1_3 are down-converted to base band after receiving the radiofrequency signal of self terminal 0, carry out baseband signal and receive the rear restoring data information of process, and carry out Nonlinear Transformation in Frequency Offset Estimation and timing frequency deviation and estimate, carry out the judgement of whether relaying;
3) terminal 1_1, terminal 1_2 and terminal 1_3 judgement needs relaying, carries out after baseband signal launches process, correcting carrier wave frequency deviation and timing frequency deviation in advance to the data message of required relaying, and upconverts to radio-frequency carrier and get on, and launches at time slot 2;
4) second level relaying: terminal 2_1 receives the radiofrequency signal of self terminal 1_1 and terminal 1_2, terminal 2_2 receives the radiofrequency signal of self terminal 1_1, terminal 1_2 and terminal 1_3, terminal 2_3 receives the radiofrequency signal of self terminal 1_3, and terminal 2_4 receives the radiofrequency signal of self terminal 1_3; Then be down-converted to base band, carry out baseband signal and receive restoring data information after process, and carry out Nonlinear Transformation in Frequency Offset Estimation and timing frequency deviation and estimate, carry out the judgement of whether relaying;
5) terminal 2_1, terminal 2_2, terminal 2_3 and terminal 2_4 judgement needs relaying, carries out after baseband signal launches process, correcting carrier wave frequency deviation and timing frequency deviation in advance to the data message of required relaying, and upconverts to radio-frequency carrier and get on, and launches at time slot 3;
6) third level relaying: terminal 3_1 receives the radiofrequency signal of self terminal 2_1 and terminal 2_2, and terminal 3_2 receives the radiofrequency signal of self terminal 2_1, terminal 2_2, terminal 2_3 and terminal 2_4; Then be down-converted to base band, carry out baseband signal and receive restoring data information after process, and carry out Nonlinear Transformation in Frequency Offset Estimation and timing frequency deviation and estimate, carry out the judgement of whether relaying;
7) terminal 3_1 and terminal 3_2 judgement needs relaying, carries out after baseband signal launches process, correcting carrier wave frequency deviation and timing frequency deviation in advance to the data message of required relaying, and upconverts to radio-frequency carrier and get on, and launches at time slot 4;
8) terminal 4 is down-converted to base band after receiving the radiofrequency signal of self terminal 3_1 and terminal 3_2, carries out baseband signal and receives the rear restoring data information of process.
Step 2 in above-described embodiment 2), step 4) and step 6) described in decision method be: when the data message of reduction is errorless and received signal quality just carries out relaying after reaching preset standard.Received signal quality is one or more combination of Received signal strength field intensity, decoding iteration number of times and synchronized tracking precision.
The errorless detection mode of above-mentioned data message can be:
Execution mode one: whether successfully judged by CRC check, CRC check success then illustrates that data message is errorless, and CRC check failure then illustrates that data message is wrong;
Execution mode two: whether reach maximum iteration time to judge by the iterations of decoding, then illustrate that when decoding iteration number does not reach maximum iteration time data message is errorless, then illustrate that when decoding iteration number reaches maximum iteration time data message is wrong.
The execution mode of above-mentioned received signal quality preset standard can be:
Execution mode one: Received signal strength field intensity is not less than-90dBm and iterations is not more than 1/2 of maximum iteration time and synchronized tracking precision reaches error is less than 1%;
Execution mode two: Received signal strength field intensity is greater than-80dBm and iterations is less than 1/3 of maximum iteration time and synchronized tracking precision reaches error is not more than 5 ‰;
Execution mode three: Received signal strength field intensity is not less than-70dBm and iterations is not more than 1/4 of maximum iteration time and synchronized tracking precision reaches error is less than 1 ‰;
Execution mode four: Received signal strength field intensity is not less than-75dBm;
Execution mode five: iterations is not more than 30% of maximum iteration time;
Execution mode six: synchronized tracking precision reaches error and is less than 3 ‰;
Execution mode seven: Received signal strength field intensity is greater than-80dBm and iterations is less than 1/3 of maximum iteration time;
Execution mode eight: Received signal strength field intensity is greater than-83dBm, synchronized tracking precision reaches error and is not more than 7 ‰;
Execution mode nine: iterations is less than 1/2 of maximum iteration time and synchronized tracking precision reaches error is not more than 1 ‰.
The various threshold value settings of above-mentioned received signal quality preset standard and various compound mode are all contents that the present invention protects.
Step 2 in above-described embodiment 2), step 4) and step 6) described in the execution mode of carrier frequency bias estimation can be:
Execution mode one: the pilot tone estimation technique, the incremental change statistics of the phase deviation namely at pilot tone place obtains Nonlinear Transformation in Frequency Offset Estimation divided by pilot tone incremental number;
Execution mode two: frame synchronization sequence Correlation Estimation Method, namely, after utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, Nonlinear Transformation in Frequency Offset Estimation can be obtained by the phase deviation of adjacent two relevant peaks divided by the distance of adjacent two relevant peaks.
Step 2 in above-described embodiment 2), step 4) and step 6) described in the execution mode of timing frequency deviation method of estimation can be:
Execution mode one: the pilot tone estimation technique, the time deviation amount namely at pilot tone place obtains timing frequency deviation divided by pilot tone incremental number and estimates;
Execution mode two: frame synchronization sequence Correlation Estimation Method, namely, after utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, timing frequency deviation can be obtained by the time migration of adjacent two relevant peaks divided by the distance of adjacent two relevant peaks and estimate.
Step 3 in above-described embodiment 2), step 5) and step 7) described in carrier wave frequency deviation antidote be conjugation multiplication, namely carry out conjugation multiplication with estimated the carrier wave frequency deviation phase shift sequence formed and the signal launched.
Step 3 in above-described embodiment 2), step 5) and step 7) described in timing frequency deviation antidote be filtering interpolation, its execution mode can be:
Execution mode one: realized by FIR interpolation filter;
Execution mode two: realized by IIR interpolation filter;
Execution mode three: by after being fourier transformed into frequency domain by carrying out Fourier inversion realization again after filtering frequency response multiplication.
Step 1 in above-described embodiment 2), step 3), step 5) and step 7) described in baseband signal launch process and comprise: coding, intertexture, pilots insertion, signal framing, filtering are shaping.
Wherein, the execution mode of coding can be one or more the cascading in convolution code, Reed-solomon (RS) code, LDPC code, Turbo code;
Wherein, the execution mode of intertexture can be the one of convolutional interleave, block interleaving;
Wherein, the execution mode of pilots insertion can be one or both combination of scattered pilot, continuous pilot;
Wherein, the execution mode of signal framing can be by before Frame or the mode inserting frame synchronization sequence below realize;
Wherein, the execution mode that filtering is shaped can be the one of raised cosine roll off filtering, square root raised cosine filter, matched filtering, butterworth filter, Chebyshev filtering.
Step 2 in above-described embodiment 2), step 4), step 6) and step 8) described in baseband signal receive process comprise: filtering, carrier synchronization, Timing Synchronization, frame synchronization, channel estimating, channel equalization, deinterleaving, decoding.
Wherein, the execution mode of filtering can be the one of raised cosine roll off filtering, square root raised cosine filter, matched filtering, butterworth filter, Chebyshev filtering;
Wherein, the execution mode of carrier synchronization is catching of pilot frequency carrier wave information and follows the tracks of;
Wherein, the execution mode of Timing Synchronization is catching of pilot tone timing information and follows the tracks of;
Wherein, the execution mode of frame synchronization is catching of frame synchronization sequence relevant peaks and follows the tracks of;
Wherein, the execution mode of channel estimating can be channel estimation in frequency domain, time domain channel is estimated, coherent channel is estimated, the one of incoherent channel estimating;
Wherein, the execution mode of channel equalization can be the one of frequency domain equalization, time domain equalization, feedback equalization;
Wherein, the execution mode of deinterleaving can be the one of convolution de-interleaving, block deinterleaving;
Wherein, the execution mode of decoding can be one or more the cascading in convolution decoder, Reed-solomon (RS) decoding, LDPC decoding, Turbo decoding.
In example 2, number of timeslots can also be the positive integers arbitrarily such as 2,3,5,6,8, and terminal quantity can also be the positive integers arbitrarily such as 3,4,5,6,16, and relaying jumping figure can also be the positive integers arbitrarily such as 1,2,3,5,6,8.Any selection of number of timeslots, terminal quantity, relaying jumping figure is all contents that the present invention protects.
Embodiment 3
The relay for radio communication that the present invention proposes as shown in Figure 5.For a relay for radio communication, it contains:
System control module: it is connected with data selecting module, provides data selection control signal to data selecting module, for the selection of control data information; It is connected with transceiving radio frequency switch module, and provide transmitting-receiving control signal to transceiving radio frequency switch module, the transmitting-receiving carrying out radiofrequency signal controls; It is connected with timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, obtains timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation; It is connected with baseband signal receiver module, obtains field intensity and iterations, carries out relay decision, generates predistortion control signal; It is connected with timing frequency deviation and carrier wave frequency deviation rectification module, provides predistortion control signal to timing frequency deviation and carrier wave frequency deviation rectification module, for controlling the predistortion of timing frequency deviation and carrier wave frequency deviation;
Data selecting module: it is connected with system control module, baseband signal receiver module, baseband signal transmitter module, select one of to export, as the data message giving baseband signal transmitter module from the data message input of outside and the data message from baseband signal receiver module according to data selection control signal; When system is in general modfel, select the data message from outside to input, when system is in repeater mode, select the data message from baseband signal receiver module to export;
Baseband transmission module, it is connected with data selecting module, timing frequency deviation and carrier wave frequency deviation rectification module, is carried out by the data message exported giving timing frequency deviation and carrier wave frequency deviation rectification module after baseband signal launches process from data selecting module;
Timing frequency deviation and carrier wave frequency deviation rectification module: it is connected with baseband signal transmitter module, system control module, up-converter module, the predistortion control signal provided according to system control module gives up-converter module after carrying out the rectification of timing frequency deviation and carrier wave frequency deviation to the base band transmit exported from baseband signal transmitter module;
Up-converter module: it with timing frequency deviation and carrier wave frequency deviation rectification module, radio-frequency switch module be connected, the base band transmit after timing frequency deviation and the process of carrier wave frequency deviation rectification module is carried out upconverting to radio frequency, and gives radio-frequency switch module;
Radio-frequency switch module: it is connected with up-converter module, down conversion module, system control module, according to the transmitting-receiving control signal that system control module provides, carry out radio-frequency (RF) switch control, when receiving and dispatching control signal and being in emission state, the radiofrequency signal that up-converter module exports is delivered on radio-frequency carrier, when receiving and dispatching control signal and being in accepting state, give down conversion module by the radiofrequency signal on radio-frequency carrier;
Down conversion module: it is connected with radio-frequency switch module, timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, baseband signal receiver module, radiofrequency signal is obtained from radio-frequency switch module, export baseband receiving signals after carrying out down-converted, and give timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, baseband signal receiver module;
Timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module: it is connected with down conversion module, system control module, after down conversion module obtains baseband receiving signals, carry out timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation, and give system control module by estimated timing frequency deviation and carrier wave frequency deviation;
Baseband signal receiver module: it is connected with down conversion module, data selecting module, system control module, baseband signal reception process is carried out after down conversion module obtains baseband receiving signals, data selecting module is given by the data message obtained after process, export simultaneously, give system control module by the field intensity obtained after process and iterations information.
Baseband signal transmitter module described in above-described embodiment 3 comprises coding module, interleaving block, pilots insertion module, signal framing module, filtering forming module, as shown in Figure 6.
Wherein, the execution mode of coding module can be one or more the cascading in convolution code module, Reed-solomon (RS) code module, LDPC code module, Turbo code module;
Wherein, the execution mode of interleaving block can be the one of convolutional interleave module, block interleaving module;
Wherein, the execution mode of pilots insertion module can be one or both combination of scattered pilot module, continuous pilot module;
Wherein, the execution mode of signal framing module can be by before Frame or the module inserting frame synchronization sequence below realize;
Wherein, the execution mode of filtering shaping module can be the one of raised cosine roll off filtration module, square root raised cosine filter module, matched filtering module, butterworth filter module, Chebyshev filtration module.
Baseband signal receiver module described in above-described embodiment 3 comprises filtration module, carrier synchronization module, SNR detection module, frame synchronization module, channel estimation module, channel equalization module, de-interleaving block, decoder module, as shown in Figure 7.
Wherein, the execution mode of filtration module can be the one of raised cosine roll off filtration module, square root raised cosine filter module, matched filtering module, butterworth filter module, Chebyshev filtration module;
Wherein, the execution mode of carrier synchronization module is catching of pilot frequency carrier wave information and tracking module;
Wherein, the execution mode of SNR detection module is catching of pilot tone timing information and tracking module;
Wherein, the execution mode of frame synchronization module is catching of frame synchronization sequence relevant peaks and tracking module;
Wherein, the execution mode of channel estimation module can be the one of channel estimation in frequency domain module, time domain channel estimation module, coherent channel estimation module, incoherent channel estimation module;
Wherein, the execution mode of channel equalization module can be the one of frequency domain equalization module, time domain equalization module, feedback equalization module;
Wherein, the execution mode of de-interleaving block can be the one of convolution de-interleaving module, block de-interleaving block;
Wherein, the execution mode of decoder module can be one or more the cascading in convolution decoder module, Reed-solomon (RS) decoder module, LDPC decoder module, Turbo decoder module.
Timing frequency deviation described in above-described embodiment 3 and carrier wave frequency deviation rectification module comprise timing frequency deviation rectification module and carrier wave frequency deviation rectification module.
Above-mentioned timing frequency deviation rectification module is filtering interpolation module, and its execution mode can be:
Execution mode one: realized by FIR interpolation filtering module;
Execution mode two: realized by IIR interpolation filtering module;
Execution mode three: realized by the module of carrying out Fourier inversion after filtering frequency response multiplication again after being fourier transformed into frequency domain.
Above-mentioned carrier wave frequency deviation rectification module is conjugation multiplier module.
Timing frequency deviation described in above-described embodiment 3 and Nonlinear Transformation in Frequency Offset Estimation module comprise timing frequency deviation estimation module and Nonlinear Transformation in Frequency Offset Estimation module.
Above-mentioned Nonlinear Transformation in Frequency Offset Estimation module is pilot tone estimation module or frame synchronization sequence correlation estimation module, and execution mode can be:
Execution mode one: pilot tone estimation module, the incremental change of the phase deviation namely at pilot tone place adds up the module divided by pilot tone incremental number;
Execution mode two: frame synchronization sequence correlation estimation module, after namely utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, by the phase deviation of adjacent two relevant peaks module divided by adjacent two relevant peaks distances.
Above-mentioned timing frequency deviation estimation module is pilot tone estimation module or frame synchronization sequence correlation estimation module, and execution mode can be:
Execution mode one: pilot tone estimation module, the time deviation amount namely at pilot tone place is divided by the module of pilot tone incremental number;
Execution mode two: frame synchronization sequence correlation estimation module, after namely utilizing local frame synchronization sequence and the frame synchronization sequence that receives to carry out related calculation, by the time migration of adjacent two relevant peaks module divided by adjacent two relevant peaks distances.
System control module described in above-described embodiment 3 comprises relay decision module, and this relay decision module comprises the errorless decision device of data message and received signal quality decision device.
The execution mode of the errorless decision device of above-mentioned data message can be:
Execution mode one: realized by CRC check decision device, CRC check success then illustrates that data message is errorless, and CRC check failure then illustrates that data message is wrong;
Execution mode two: realized by decoding iteration number decision device, is then illustrated that when decoding iteration number does not reach maximum iteration time data message is errorless, then illustrates that data message is wrong when decoding iteration number reaches maximum iteration time.
Above-mentioned received signal quality decision device comprises one or more cascading of Received signal strength field intensity decision device, decoding iteration number of times decision device and synchronized tracking precision decision device, and execution mode can be:
Execution mode one: realize with the cascade of Received signal strength field intensity decision device, decoding iteration number of times decision device and synchronized tracking precision decision device, judgement standard is: Received signal strength field intensity is not less than-90dBm and iterations is not more than 1/2 of maximum iteration time and synchronized tracking precision reaches error is less than 1%;
Execution mode two: realize with the cascade of Received signal strength field intensity decision device, decoding iteration number of times decision device and synchronized tracking precision decision device, judgement standard is: Received signal strength field intensity is greater than-80dBm and iterations is less than 1/3 of maximum iteration time and synchronized tracking precision reaches error is not more than 5 ‰;
Execution mode three: realize with the cascade of Received signal strength field intensity decision device, decoding iteration number of times decision device and synchronized tracking precision decision device, judgement standard is: Received signal strength field intensity is not less than-70dBm and iterations is not more than 1/4 of maximum iteration time and synchronized tracking precision reaches error is less than 1 ‰;
Execution mode four: only use Received signal strength field intensity decision device, judgement standard is: Received signal strength field intensity is not less than-75dBm;
Execution mode five: only use decoding iteration number of times decision device, judgement standard is: iterations is not more than 30% of maximum iteration time;
Execution mode six: only use synchronized tracking precision decision device, judgement standard is: synchronized tracking precision reaches error and is less than 3 ‰;
Execution mode seven: realize with the cascade of Received signal strength field intensity decision device, decoding iteration number of times decision device, judgement standard is: Received signal strength field intensity is greater than-80dBm and iterations is less than 1/3 of maximum iteration time;
Execution mode eight: realize with the cascade of Received signal strength field intensity decision device, synchronized tracking precision decision device, judgement standard is: Received signal strength field intensity is greater than-83dBm, synchronized tracking precision reaches error and is not more than 7 ‰;
Execution mode nine: realize with the cascade of decoding iteration number of times decision device and synchronized tracking precision decision device, judgement standard is: iterations is less than 1/2 of maximum iteration time and synchronized tracking precision reaches error is not more than 1 ‰.
The various threshold value settings of above-mentioned received signal quality preset standard and various compound mode are all contents that the present invention protects.
Above execution mode is only for illustration of the present invention, and be not limitation of the present invention, the those of ordinary skill of relevant technical field, without departing from the spirit and scope of the present invention, can also make a variety of changes and modification, therefore all equivalent technical schemes also belong to category of the present invention.
Claims (10)
1. the relay for radio communication, it is characterized in that, this relay comprises system control module, data selecting module, baseband signal transmitter module, timing frequency deviation and carrier wave frequency deviation rectification module, up-converter module, transceiving radio frequency switch module, down conversion module, timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, baseband signal receiver module, wherein:
Described system control module is connected with data selecting module, provides data selection control signal to data selecting module, for the selection of control data information; And described system control module is connected with transceiving radio frequency switch module, provide transmitting-receiving control signal to transceiving radio frequency switch module, the transmitting-receiving carrying out radiofrequency signal controls; And described system control module is connected with timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, obtain timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation; And described system control module is connected with baseband signal receiver module, obtains field intensity and iterations, carry out relay decision, generate predistortion control signal; And described system control module is connected with timing frequency deviation and carrier wave frequency deviation rectification module, provide predistortion control signal to timing frequency deviation and carrier wave frequency deviation rectification module, for controlling the predistortion of timing frequency deviation and carrier wave frequency deviation;
Described data selecting module is connected with system control module, baseband signal receiver module, baseband signal transmitter module, select one of to export, as the data message giving baseband signal transmitter module from the data message input of outside and the data message from baseband signal receiver module according to data selection control signal; When system is in general modfel, select the data message from outside to input, when system is in repeater mode, select the data message from baseband signal receiver module to export;
Described baseband transmission module is connected with data selecting module, timing frequency deviation and carrier wave frequency deviation rectification module, is carried out by the data message exported giving timing frequency deviation and carrier wave frequency deviation rectification module after baseband signal launches process from data selecting module;
Described timing frequency deviation and carrier wave frequency deviation rectification module are connected with baseband signal transmitter module, system control module, up-converter module, the predistortion control signal provided according to system control module gives up-converter module after carrying out the rectification of timing frequency deviation and carrier wave frequency deviation to the base band transmit exported from baseband signal transmitter module;
Described up-converter module and timing frequency deviation and carrier wave frequency deviation rectification module, radio-frequency switch module are connected, and the base band transmit after timing frequency deviation and the process of carrier wave frequency deviation rectification module are carried out upconverting to radio frequency, and give radio-frequency switch module;
Described radio-frequency switch module is connected with up-converter module, down conversion module, system control module, according to the transmitting-receiving control signal that system control module provides, carry out radio-frequency (RF) switch control, when receiving and dispatching control signal and being in emission state, the radiofrequency signal that up-converter module exports is delivered on radio-frequency carrier, when receiving and dispatching control signal and being in accepting state, give down conversion module by the radiofrequency signal on radio-frequency carrier;
Described down conversion module is connected with radio-frequency switch module, timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, baseband signal receiver module, radiofrequency signal is obtained from radio-frequency switch module, export baseband receiving signals after carrying out down-converted, and give timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module, baseband signal receiver module;
Described timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module are connected with down conversion module, system control module, after down conversion module obtains baseband receiving signals, carry out timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation, and give system control module by estimated timing frequency deviation and carrier wave frequency deviation;
Described baseband signal receiver module is connected with down conversion module, data selecting module, system control module, baseband signal reception process is carried out after down conversion module obtains baseband receiving signals, data selecting module is given by the data message obtained after process, export simultaneously, give system control module by the field intensity obtained after process and iterations information.
2. relay according to claim 1, is characterized in that, described baseband signal transmitter module comprises coding module, interleaving block, pilots insertion module, signal framing module, filtering forming module.
3. relay according to claim 1, it is characterized in that, described baseband signal receiver module comprises filtration module, carrier synchronization module, SNR detection module, frame synchronization module, channel estimation module, channel equalization module, de-interleaving block, decoder module.
4. relay according to claim 1, is characterized in that, described timing frequency deviation and carrier wave frequency deviation rectification module comprise timing frequency deviation rectification module and carrier wave frequency deviation rectification module, and wherein, timing frequency deviation rectification module is filtering interpolation module.
5. relay according to claim 1, is characterized in that, described timing frequency deviation and carrier wave frequency deviation rectification module comprise timing frequency deviation rectification module and carrier wave frequency deviation rectification module, and wherein, carrier wave frequency deviation rectification module is conjugation multiplier module.
6. relay according to claim 1, it is characterized in that, described timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module comprise timing frequency deviation estimation module and Nonlinear Transformation in Frequency Offset Estimation module, and wherein, Nonlinear Transformation in Frequency Offset Estimation module is pilot tone estimation module or frame synchronization sequence correlation estimation module.
7. relay according to claim 1, it is characterized in that, described timing frequency deviation and Nonlinear Transformation in Frequency Offset Estimation module comprise timing frequency deviation estimation module and Nonlinear Transformation in Frequency Offset Estimation module, and wherein, timing frequency deviation estimation module is pilot tone estimation module or frame synchronization sequence correlation estimation module.
8. relay according to claim 1, is characterized in that, described system control module comprises relay decision module, and this relay decision module comprises the errorless decision device of data message and received signal quality decision device.
9. relay according to claim 8, is characterized in that, described received signal quality decision device comprises one or more the cascading in Received signal strength field strength detectors, decoding iteration number of times detector and synchronized tracking precision detecting device.
10. for a trunking method for radio communication, it is characterized in that, this trunking method uses the described relay apparatus of one of claim 1-9 to carry out.
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