CN1479465A - Wave beam judgeing method and device used in switching wave beam type intelligent antenna system - Google Patents
Wave beam judgeing method and device used in switching wave beam type intelligent antenna system Download PDFInfo
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Abstract
Dual thresholds are introduced in the method to be as criterions to determine whether number of time of occurring optimal signal quality index is changed obviously. It is ensured to switch wave beam only when number of time of occurring optimal signal quality index in a period of time with fixed sampling speed is changed obviously, and the corresponding wave beam is not the present wave beam in user's location. Otherwise, wave beam in user's location is hold unchanged. Thus, if influence of wave beam on user is not large, the invention reduces number of time to switch wave beam for users in boundary of wave beams, and if user's location is changed, switching wave beam is completed.
Description
Technical field
The present invention relates to the method for reseptance and the device of wireless communication system, particularly a kind of wave beam decision method and device that is used for switching-beam type antenna system.
Background technology
In wireless communication system, subscriber equipment and base station are by the wireless channel transmitting signal.Compare with wire message way, wireless channel environment is comparatively abominable, has many interference such as decline, multipath, so the method for receiving and processing signal in the wireless communication system is a decisive factor that directly influences systematic function always.
Code division multiple access (Code Division Multiple Access is designated hereinafter simply as CDMA) system also has the above-mentioned feature of wireless communication system as a kind of wireless communication system.And in this system, a plurality of users transmit at the shared same frequency of synchronization, so also there is self-interference, be that different user disturbs each other, claim multiple access to disturb (Multiple Access Interference abbreviates MAI as) again, thereby make the reception of wireless signal difficult more.But because cdma system has that power system capacity is big, the availability of frequency spectrum is high, background noise suppresses characteristics such as the strong and good confidentiality of ability, so become one of mainstream technology of radio communication just gradually.
, adopt technology such as time diversity, antenna diversity traditionally for thereby the receiving ability that improves wireless signal increases the capacity of system.Though adopt these technology to obtain certain effect, the development of technology and the demand of practical application receive for the system wireless signal and have higher requirement.In recent years, along with Multiuser Detection (MultiUser Detection, abbreviate MDI as) development of technology, adaptive equalization technique and smart antenna (Smart Antenna) technology, may for improving further that cdma system provides for the receptivity of wireless signal.Wherein, intelligent antenna technology derives from array antenna (Array Antenna) technology in the military technology, belong to a kind of space diversity method by spatial information difference different user, it passes through Digital Signal Processing, making antenna array is that each user carries out wave beam forming adaptively, is equivalent to form the high-gain aerial that can follow the tracks of it for each user.
As shown in Figure 1, a typical antenna system can be divided into three parts: signal receiving unit, wave beam form unit and weights determining unit, below are described respectively.
Wave beam forms unit 11 and is used to each user to carry out wave beam forming, and it comprises complex multiplier group (1111~111N forms by complex multiplier) and complex adder 112.Complex multiplier 1111~111N in the complex multiplier group finishes the corresponding weights ω that signal and weights determining unit provide after the demodulation of signal receiving unit 10 output
i(i=1,2 ... N) multiplying between also exports signal to complex adder.Complex adder is to the output result summation and the output signal r of complex multiplier.Output signal r as the output of whole antenna system, also offers weights determining unit 12 on the one hand on the other hand.
Antenna system can be divided into intermediate frequency antenna system and base band antenna system two big classes according to the size of pending signal center frequency.In the intermediate frequency antenna system, the output X of each radio-frequency channel of signal receiving unit
1~X
NThe centre frequency that forms the output r of unit with wave beam belongs to intermediate-freuqncy signal.Its processing method is not distinguish the user.Adopt such antenna system can form " intelligent residential district " (Smart Cell), improve the quality of reception of system by the overlay area of regulating the sub-district.In the base band antenna system, the output X of each radio-frequency channel of signal receiving unit
1~X
NThe centre frequency that forms the output r of unit with wave beam belongs to baseband signal.Its processing method is to distinguish or not distinguish the user, but the general processing method that adopts the difference user.Adopt such antenna system can form corresponding received beam, thereby obtain better receptivity different users.
Cdma system is owing to existing a plurality of different users that transmit in the same moment and same frequency, so if adopt the intermediate frequency type antenna system of not distinguishing the user, then reception is not good.And if user's base band type antenna system is distinguished in employing, then reception generally is better than intermediate frequency type antenna system.So, generally adopt base band type antenna system to improve the quality of reception for cdma system.
Base band type antenna system determines that according to weights the difference of method can be divided into three types of switching-beam (SwitchBeamed) type antenna system, arrival direction angle (DOA, Direction Of Arrived) type antenna system and self adaptation (Adaptive) type antenna systems.
Switching-beam type antenna system utilizes aerial array to be pre-formed a plurality of narrow directional beams, points to all directions respectively, is equivalent to cover N angular zone with N antenna.When the mobile subscriber is moved, such antenna system is determined wave beam under the customer location by detection signal strength, utilize the weights corresponding of storage in advance that this user is finished wave beam forming to obtain best output signal then, promptly switch to the affiliated wave beam of customer location with each wave beam.As shown in Figure 2, the weights determining unit of typical switching-beam type antenna system is searched module three parts by beam signal quality index computing module, wave beam judging module and weights and is constituted, wherein, received signal is made of the signal component of each wave beam and the quality index V of each component
1, V
2V
MBe different, the quality indication signal of these components is calculated by beam signal quality index calculation element to be determined; The wave beam judgment device is according to quality indication signal V
1, V
2V
MDetermine the wave beam under the customer location and export the corresponding label Index of this wave beam; Weights are searched device and are found out corresponding weights ω according to the label of wave beam
1, ω
2, ω
N, this installs general available look-up table or database is realized.
Fig. 3 is the antenna direction schematic diagram of switching-beam antenna system.Point O (30) is a base station location, and 311 and 312 is two definite wave beam area I and wave beam zone II, has the common area I II that covers of part between them.If the user side is to the center line that is positioned at wave beam I, promptly be arranged in figure A position 321, then it belongs to wave beam I, in other words, to the quality index optimum of signal component that should wave beam I, therefore this user is adopted wave beam I in this subscriber signal that base-station antenna array receives; If the user side is to being positioned on two wave beam interface points and the base station line, promptly be arranged in figure B position 322, then theoretically, in this subscriber signal that base-station antenna array receives to should wave beam I and the quality index of the signal component of II equate, so the user can to belong to wave beam I also can be wave beam II.But consider the influence of factors such as noise, the quality indication signal 41 of the signal component of wave beam I and II and 42 will fluctuate around ideal value 40 as shown in Figure 4 in time.If according to who big who excellent principle, the wave beam of higher value correspondence is as wave beam under the customer location in the promptly selected quality indication signal 41 and 42, certainly will cause then that wave beam frequently switches as shown in Figure 4 under the user between I and II, and along with the increase of noise, switching frequency will increase thereupon also.Consider that general switching-beam type smart antenna is directly used in downlink, this frequent switching may make subscriber equipment constantly carry out soft/More Soft Handoff, thereby a large amount of consume system resources has increased system cost.
Summary of the invention
Therefore the purpose of this invention is to provide a kind of wave beam decision method that is used for switching-beam type antenna system, under the little prerequisite of customer impact that it can signal be stronger in to wave beam, reduce wave beam intersection user's switching times and when customer location changes, finish the wave beam switching.
According to the wave beam decision method that is used for switching-beam type antenna system of the present invention, described antenna system receives each subscriber signal of the signal component that comprises corresponding each wave beam and calculates the quality indication signal of each signal component, wherein, under determining each customer location, system carries out following steps during wave beam:
(1) some each wave beams that engrave uniformly-spaced the time that will set quantity add up respectively as the optimum occurrence number of optimal beam, and wherein, described optimal beam has the pairing wave beam of signal component of optimum signal quality index constantly for each; And
(2) optimum occurrence number and the predefined first threshold with maximum compares, if the optimum occurrence number of described maximum less than predefined first threshold and customer location current under the optimum occurrence number of wave beam more than or equal to predefined second threshold value, perhaps the optimum occurrence number of described maximum is less than predefined second threshold value, determine that then customer location still belongs to current affiliated wave beam, otherwise, determine that customer location belongs to the wave beam with maximum optimum occurrence number, wherein, described first threshold is greater than described second threshold value.
Therefore another object of the present invention provides a kind of wave beam judgment device that is used for switching-beam type antenna system, under the little prerequisite of customer impact that it can signal be stronger in to wave beam, reduce wave beam intersection user's switching times and when customer location changes, finish the wave beam switching.
According to the wave beam judgment device that is used for switching-beam type antenna system of the present invention, the weights determining unit of described antenna system is searched device by beam signal quality index calculation element, wave beam judgment device and weights and is formed, beam signal quality index calculation element calculates the quality indication signal of the signal component of corresponding each wave beam in each subscriber signal, weights are searched device and are searched corresponding weights according to wave beam under the definite customer location of wave beam judgment device, wherein, described wave beam judgment device comprises:
The optimal beam selected cell, its calculate from described beam signal quality index calculation element each select to have the optimal beam of the pairing wave beam of signal component of optimum signal quality index the quality indication signal of each wave beam respective signal component constantly as this moment;
The statistical disposition unit, its to set quantity some uniformly-spaced constantly the selected optimal beam occurrence number of the above optimal beam selected cell add up respectively with definite each wave beam in these some optimum occurrence numbers that engrave uniformly-spaced the time; And
The wave beam decision unit, maximum optimum occurrence number and the comparison of predefined first threshold in optimum occurrence number of each wave beam that the statistical disposition unit is obtained, if maximum optimum occurrence number less than predefined first threshold and customer location current under the optimum occurrence number of wave beam more than or equal to predefined second threshold value, perhaps the optimum occurrence number of described maximum is less than predefined second threshold value, determine that then customer location belongs to current affiliated wave beam, otherwise, determine that customer location belongs to the wave beam with maximum optimum occurrence number, wherein, described first threshold is greater than described second threshold value.
Therefore, owing to adopt dual threshold need to judge whether switching-beam, therefore can avoid or reduce the frequent switching of user's wave beam when two wave beam overlapping regions, reduce system cost and improved the reliability of system.
Description of drawings
By below in conjunction with the description of accompanying drawing to preferred embodiment of the present invention, can further understand all types of target of the present invention, advantage and characteristics, wherein:
Fig. 1 is the structural representation of antenna system;
Fig. 2 determines the structural representation of device for weights in the switching-beam antenna system;
Fig. 3 is the antenna direction schematic diagram of switching-beam antenna system;
The signal wave beam I that base station intelligent antenna received when Fig. 4 was arranged in B place, Fig. 3 position for the user and the quality indication signal of II component be curve chart over time;
Fig. 5 is the flow chart of weights deterministic process, and this process has comprised according to wave beam decision method of the present invention preferred embodiment; And
Fig. 6 is the structural representation according to wave beam judgment device of the present invention preferred embodiment.
Embodiment
Below be the noise characteristic that example is described each beam signal component with Fig. 4.The time that the quality indication signal of supposing the wave beam I respective signal component that records in a period of time [0, T] is better than the quality indication signal of wave beam II respective signal component is t
12, the time that the quality indication signal of the wave beam II respective signal component that records is better than the quality indication signal of wave beam I respective signal component is t
21, the noise of two wave beam I and II is independent identically distributed, then can prove t from mathematics
12=t
21=T/2.According to studies confirm that, noise in the signal component of each wave beam is independent identically distributed, therefore for the situation of two wave beam I among Fig. 4 and II, when in the certain hour section during with the quality indication signal of the signal component of two wave beams of fixed rate sampled measurements, there are following corresponding relation in the distribution and the customer location of each measured beam signal quality index:
When customer location is that angle that A or subscriber signal arrive antenna for base station is when being in the position A that wave beam I concentrates, the optimum occurrence number of the quality indication signal of wave beam I is maximum in the quality indication signal that at every turn records, in other words, the ratio that this occurrence number accounts for total sampling number is the highest, and the signal of the wave beam that other occurrence numbers are less is considered as noise effect; When customer location is that angle that B or subscriber signal arrive antenna for base station is when being in the intersection B of two wave beam I and II, optimum or the maximum occurrence number of the quality indication signal of wave beam I and wave beam II is almost equal and to account for the ratio of total sampling number higher in the quality indication signal that at every turn records, and the signal of the wave beam that other occurrence numbers are less is considered as noise effect; When the III place, boundary that the angle that arrives antenna for base station when subscriber signal is in two wave beam I and II still is partial to the center (being between A and the B) of a wave beam I, it is higher that the optimum or maximum occurrence number of the quality indication signal of wave beam I and wave beam II accounts for the ratio of total sampling number in the quality indication signal that at every turn records, and the signal of the less wave beam of other occurrence numbers is considered as noise effect, but the optimum or maximum occurrence number of wave beam I signal quality index greater than wave beam II quality indication signal optimum or maximum occurrence number.
According to the distribution of each beam signal quality index and the above-mentioned corresponding relation of customer location, wave beam decision method of the present invention has only when the optimum occurrence number generation significant change of the quality indication signal of wave beam in a period of time that records with fixed sample rate and should the correspondence wave beam is not under the customer location during current wave beam, just determine wave beam under the customer location is switched to the maximum wave beam of the optimum occurrence number of quality indication signal, otherwise, wave beam is constant under keeping the active user position, has obviously reduced the wave beam switching times thus.In order to judge whether the optimum occurrence number of quality indication signal significant change takes place, the present invention introduces dual threshold as the criterion standard, promptly, if the optimum occurrence number of the quality indication signal of wave beam is all less than the optimum occurrence number of the quality indication signal of wave beam under a bigger threshold value and the active user position during more than or equal to another less threshold value, perhaps the quality indication signal of wave beam is all less than the second less threshold value, then be considered as not taking place significant change, has only the optimum occurrence number of the quality indication signal of working as a certain wave beam all more than or equal to this bigger threshold value, though but the optimum occurrence number of quality indication signal that does not perhaps have to surpass a wave beam under the bigger threshold value active user position during less than another less threshold value, just is considered as taking place significant change.The concrete numerical value of the above-mentioned first threshold and second threshold value can be determined by emulation according to the actual conditions of wireless communication system.
Fig. 5 is the flow chart of weights deterministic process, and this process has comprised according to wave beam decision method of the present invention preferred embodiment.As shown in Figure 5, in step 1.1, antenna system receives each user's wireless signal by aerial array, and to corresponding radio-frequency channel output radiofrequency signal; Subsequently, in step 1.2, each radio-frequency channel is carried out the radiofrequency signal of input power amplification, channel correcting, demodulation and matched filter processing and is formed the pending baseband signal of unit output to weights determining unit and wave beam.It below is the weights deterministic process.In step 2.1, each subscriber signal that is converted to baseband signal has comprised the signal component of corresponding each wave beam, at first by the weights determining unit calculate equally spaced each constantly the quality indication signal of the signal component of each wave beam and the wave beam of signal component correspondence of choosing the quality indication signal optimum as optimal beam; Subsequently in step 2.2, the label of this optimal beam is carried out differential counting, that is, the occurrence number of the optimal beam that label is identical adds up; Then, judge whether total counts (also being sampling number) reaches stipulated number,, so judge promptly also whether the sampling time satisfy preseting length because sampling rate fixes in step 2.3; If counts no show stipulated number then returns step 2.1, otherwise, enter step 2.4, the result of differential counting is sorted according to size; Then, judge that whether maximum count value (i.e. Zui Da optimal beam occurrence number) is greater than threshold value thresholding N in step 2.5
1If maximum count value is more than or equal to threshold value thresholding N
1, then enter step 2.6, selected have the wave beam of this maximum count value as the wave beam of determining weights; Subsequently in step 2.7, the weights determining unit is according to above-mentioned label with wave beam of this maximum count value, and obtain corresponding weights by tabling look-up and return step 1.1 after step 2.8 is finished beam shaping offering, thus the weights deterministic process of a beginning new round.If maximum count value is less than threshold value thresholding N
1, then in step 2.9, judge whether not exist more than or equal to threshold value thresholding N
2Count value, wherein, threshold value N
2Less than N
1If there is no more than or equal to threshold value thresholding N
2Count value, then enter step 2.12, choose current under wave beam as the wave beam of determining weights and enter step 2.7, otherwise, in step 2.10, from the differential counting after the ordering, choose count value more than or equal to threshold value thresholding N
2Wave beam and enter step 2.11 subsequently, judge that count value is more than or equal to threshold value thresholding N
2Wave beam in whether comprise customer location current under wave beam.If more than or equal to threshold value thresholding N
2Wave beam in comprise customer location current under wave beam, then enter step 2.12, otherwise, enter step 2.6, choose wave beam as the wave beam of determining weights with maximum count value.
As mentioned above, the weights determining unit of antenna system is searched device by beam signal quality index calculation element, wave beam judgment device and weights and is formed, beam signal quality index calculation element calculates the quality indication signal of the signal component of corresponding each wave beam in each subscriber signal, weights are searched device and are searched corresponding weights according to wave beam under the definite customer location of wave beam judgment device, and the present invention also introduces dual threshold judgement mode in the wave beam judgment device.Particularly, the optimal beam selected cell of wave beam judgment device of the present invention calculate from beam signal quality index calculation element each select to have the optimal beam of the wave beam of optimum signal quality index the quality indication signal of each wave beam respective signal component constantly as this moment, by the statistical disposition unit the selected optimal beam of the above maximum selected cell of some moment of recording with fixed rate in certain period is added up to determine that each wave beam is in these some optimum occurrence numbers that engrave uniformly-spaced the time then, the last maximum optimum occurrence number and the comparison of predefined bigger first threshold in the optimum occurrence number of each wave beam that the statistical disposition unit is obtained by the wave beam decision unit, if maximum optimum occurrence number less than predefined first threshold and customer location current under the optimum occurrence number of wave beam more than or equal to the predefined second less threshold value, determine that then customer location belongs to current affiliated wave beam, otherwise, determine that customer location belongs to the wave beam with maximum optimum occurrence number.
Fig. 6 is the structural representation according to wave beam judgment device of the present invention preferred embodiment.The wave beam judgment device of this preferred embodiment comprises maximum selected cell 60, counting unit 61, sequencing unit 62, decision unit 63 and control unit 64.Each each beam signal quality index V constantly that maximum selected cell 60 provides from beam signal quality index calculation element with fixed rate
1, V
2V
MIn the maximum or optimum wave beam of selected quality indication signal as optimal beam and with the label Index of this wave beam
MaxOffer counting unit 62.Subsequently, the label that 61 pairs of maximum selected cells of counting unit provide carries out differential counting, the occurrence number that also is about to the identical optimal beam of label adds up, when the sum of differential counting reached regulation numerical value, counting unit 61 was with count results (being the number of times that each wave beam occurs in the regulation counts as optimal beam) N
1N
MDeliver to sequencing unit 62.62 pairs of count results of sequencing unit sort, and obtain the number of times sequence N that occurs as optimal beam according to each wave beam of big minispread
1' ... N
M'.This number of times sequence is sent to decision unit 63, and the label Index of wave beam exports weights to and searches device under the decision function of decision unit 63 completing steps, 2.4~step 2.91 or 2.92 and customer location that judgement is obtained.The function that above-mentioned maximum selected cell 60, counting unit 61, sequencing unit 62 and decision unit 63 are realized is all at the control logic C of control unit 64
0, C
1, C
2And C
3Under finish.
According to calculating, in according to method of the present invention, (being about 15K) of the data traffic is-symbol level on data/address bus and the address bus, therefore can use the central processing unit such as digital signal processor (DSP) to realize wave beam judgment device of the present invention, and the data traffic of this symbol level take the capacity of data/address bus and address bus hardly.
It is worthy of note above-mentioned quality indication signal V
1, V
2V
MEnergy value including, but not limited to each signal component of corresponding wave beam.
Claims (10)
1. wave beam decision method that is used for switching-beam type antenna system, described antenna system receives each subscriber signal of the signal component that comprises corresponding each wave beam and calculates the quality indication signal of each signal component, it is characterized in that, under system determines each customer location, carry out following steps during wave beam:
(1) some each wave beams that engrave uniformly-spaced the time that will set quantity add up respectively as the optimum occurrence number of optimal beam, and wherein, described optimal beam engraves the pairing wave beam of the signal component with optimum signal quality index uniformly-spaced the time for each; And
(2) optimum occurrence number and the predefined first threshold with maximum compares, if the optimum occurrence number of described maximum less than predefined first threshold and customer location current under the optimum occurrence number of wave beam more than or equal to predefined second threshold value, perhaps the optimum occurrence number of described maximum is less than predefined second threshold value, determine that then customer location still belongs to current affiliated wave beam, otherwise, determine that customer location belongs to the wave beam with maximum optimum occurrence number, wherein, described first threshold is greater than described second threshold value.
2. the method for claim 1 is characterized in that, step (1) may further comprise the steps:
(1a) the pairing wave beam of signal component that each is had constantly an optimum signal quality index is as the optimal beam in this moment and the optimum occurrence number of this wave beam is increased progressively once; And
(1b) if whether the optimum occurrence number sum of determining each wave beam less than described setting quantity, then returns step (1a) less than described setting quantity, otherwise enters step (2).
3. method as claimed in claim 2 is characterized in that, enter step (2) in step (1b) and comprise following steps before: each wave beam that will obtain sorts as the occurrence number of optimal beam.
4. as any described method among the claim 1-3, it is characterized in that described quality indication signal is the energy value of each signal component corresponding with wave beam.
5. as any described method in the claim 4, it is characterized in that the described first threshold and second threshold value are determined by emulation mode according to the performance of wireless communication system.
6. wave beam judgment device that is used for switching-beam type antenna system, the weights determining unit of described antenna system is searched device by beam signal quality index calculation element, wave beam judgment device and weights and is formed, beam signal quality index calculation element calculates the quality indication signal of the signal component of corresponding each wave beam in each subscriber signal, weights are searched device and are searched corresponding weights according to wave beam under the definite customer location of wave beam judgment device, it is characterized in that described wave beam judgment device comprises:
The optimal beam selected cell, its calculate from described beam signal quality index calculation element each select to have the optimal beam of the pairing wave beam of signal component of optimum signal quality index the quality indication signal of each wave beam respective signal component constantly as this moment;
The statistical disposition unit, its to set quantity some uniformly-spaced constantly the selected optimal beam occurrence number of the above optimal beam selected cell add up respectively with definite each wave beam in these some optimum occurrence numbers that engrave uniformly-spaced the time; And
The wave beam decision unit, maximum optimum occurrence number and the comparison of predefined first threshold in optimum occurrence number of each wave beam that the statistical disposition unit is obtained, if maximum optimum occurrence number less than predefined first threshold and customer location current under the optimum occurrence number of wave beam more than or equal to predefined second threshold value, perhaps the optimum occurrence number of described maximum is less than predefined second threshold value, determine that then customer location belongs to current affiliated wave beam, otherwise, determine that customer location belongs to the wave beam with maximum optimum occurrence number, wherein, described first threshold is greater than described second threshold value.
7. device as claimed in claim 6 is characterized in that, described statistical disposition unit comprises:
Counting unit, it will be set each selected wave beam of some the above optimal beam selected cells of the uniformly-spaced moment of quantity and count respectively as the optimum occurrence number of optimal beam;
Sequencing unit, each wave beam that it obtains described counting unit sorts as the occurrence number count value of optimal beam.
8. as claim 6 or 7 described devices, it is characterized in that the described first threshold and second threshold value are determined by emulation mode according to the performance of wireless communication system.
9. as claim 6 or 7 described methods, it is characterized in that described quality indication signal is the energy value of each signal component corresponding with wave beam.
10. as claim 6 or 7 described devices, it is characterized in that optimal beam selected cell, statistical disposition unit and wave beam decision unit are realized with digital signal processor (DSP).
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN1866620B (en) * | 2005-05-18 | 2011-05-25 | 普天信息技术研究院 | Method for adaptively regulating intelligent antenna wave beam width |
CN101401468B (en) * | 2006-03-13 | 2011-06-29 | 艾利森电话股份有限公司 | Advanced handover for adaptive antennas |
CN101243703B (en) * | 2005-08-22 | 2012-02-15 | 艾尔加因公司 | Optimized directional antenna system |
CN109937541A (en) * | 2016-11-11 | 2019-06-25 | 索尼公司 | Communication equipment, infrastructure equipment and method |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
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TWI660598B (en) * | 2018-03-27 | 2019-05-21 | 和碩聯合科技股份有限公司 | Antenna control method |
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2002
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1866620B (en) * | 2005-05-18 | 2011-05-25 | 普天信息技术研究院 | Method for adaptively regulating intelligent antenna wave beam width |
CN101243703B (en) * | 2005-08-22 | 2012-02-15 | 艾尔加因公司 | Optimized directional antenna system |
CN101401468B (en) * | 2006-03-13 | 2011-06-29 | 艾利森电话股份有限公司 | Advanced handover for adaptive antennas |
CN109937541A (en) * | 2016-11-11 | 2019-06-25 | 索尼公司 | Communication equipment, infrastructure equipment and method |
CN109937541B (en) * | 2016-11-11 | 2023-04-11 | 索尼公司 | Communication device, infrastructure equipment and method |
US11736174B2 (en) | 2016-11-11 | 2023-08-22 | Sony Group Corporation | Communications device, infrastructure equipment and methods |
US12047151B2 (en) | 2016-11-11 | 2024-07-23 | Sony Group Corporation | Communications device, infrastructure equipment and methods |
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