| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | SYSTEMS AND METHODS FOR CANCELLING CROSS POLARIZATION INTERFERENCE IN WIRELESS COMMUNICATION USING POLARIZATION DIVERSITY | US14520309 | 2014-10-21 | US20150036762A1 | 2015-02-05 | Emerick Vann |
| An exemplary system may comprise a first and second device and a first and second power splitter coupled to a single cable. The first device may be configured to receive a first noise signal of a first polarization, and to adaptively cancel, based on the first noise signal, first noise from the noisy signal associated with an orthogonal polarization. The second device may be configured to receive a second noise signal of a second polarization, and to adaptively cancel second noise from the noisy signal associated with an orthogonal polarization based on the second noise signal. The first power splitter may be configured to receive the first noise signal from the single cable and provide the first noise signal to the first device. The second power splitter may be configured to receive the second noise signal from the single cable and provide the second noise signal to the second device. | ||||||
| 122 | Systems and methods for cancelling cross polarization interference in wireless communication using polarization diversity | US13584794 | 2012-08-13 | US08867679B2 | 2014-10-21 | Emerick Vann |
| An exemplary system may comprise a first and second device and a first and second power splitter coupled to a single cable. The first device may be configured to receive a first noise signal of a first polarization, and to adaptively cancel, based on the first noise signal, first noise from the noisy signal associated with an orthogonal polarization. The second device may be configured to receive a second noise signal of a second polarization, and to adaptively cancel second noise from the noisy signal associated with an orthogonal polarization based on the second noise signal. The first power splitter may be configured to receive the first noise signal from the single cable and provide the first noise signal to the first device. The second power splitter may be configured to receive the second noise signal from the single cable and provide the second noise signal to the second device. | ||||||
| 123 | Co-Channel Dual Polarized Microwave Device and Method for Receiving Receive Signal | US14279048 | 2014-05-15 | US20140247863A1 | 2014-09-04 | Jun Li |
| Embodiments of the present invention disclose a co-channel dual polarized microwave device and a method. Frame synchronization is performed on a first receive signal processed by cross polarization interference cancellation and phase noise immunization is performed on the first receive signal processed by frame synchronization. Frame synchronization is performed on a second receive signal not processed by cross polarization interference cancellation and phase noise immunization is performed on the second receive signal processed by frame synchronization. The first receive signal processed by phase noise immunization and the second receive signal processed by phase noise immunization are selectively received according to a frame synchronization state signal and a signal quality signal. Delay alignment is performed on a selectively received signal according to the frame synchronization state signal to implement lossless switching in a selective receiving process. | ||||||
| 124 | Wireless communication apparatus, wireless communication system and wireless communication method | US13141743 | 2010-01-06 | US08737509B2 | 2014-05-27 | Qian Yu; Lei Huang; Masayuki Hoshino; Daichi Imamura |
| In a MIMO system using a cross-polarized antenna structure, even if no ideal XPD can be obtained, the interference between different polarized waves can be reduced to allow an effective precoding to be executed. When a MIMO communication is performed between a transmitter (250) and a receiver (260) each using a cross-polarized antenna structure, a channel estimating and precoding selection section (214) of the receiver (260) performs a channel estimation of MIMO channels from the transmitter to the receiver, decides a precoding matrix (P) of a projection matrix for mutually orthogonalizing or substantially orthogonalizing the channel response matrixes for respective different polarized waves, and feeds the determined precoding matrix (P) back to the transmitter (250). In the transmitter (250), a precoding processing section (208) applies the precoding matrix (P) to the spatial stream corresponding to one of the polarized waves to perform a precoding, thereby allowing the transmitter (250) to transmit the polarized waves with the orthogonality therebetween maintained. | ||||||
| 125 | Determining cross-polarization isolation using a modulated carrier | US12776073 | 2010-05-07 | US08576962B1 | 2013-11-05 | Michael L. Downey; Jeffrey C. Chu |
| A method of and system for determining cross-polarization isolation is described. In one embodiment, a modulated signal is obtained from a communication link. The modulated signal includes a modulated co-polarized signal component and a modulated cross-polarized signal component. Cross-polarization isolation is determined using the modulated co-polarized signal component and the modulated cross-polarized signal component. The determined cross-polarization isolation can be used to adjust an antenna. | ||||||
| 126 | Fast Cross-Pole Corrector | US13286118 | 2011-10-31 | US20130107991A1 | 2013-05-02 | Jerry R. Hinson |
| A system for correcting for an angle of rotation between a linearly polarized target signal and a dual-polarized antenna having vertical and horizontal outputs includes receiving a time series of signals from the vertical and horizontal outputs of the receive antenna, applying the vertical signals simultaneously to a data buffer and to a spectrum domain converter block to yield, respectively, spectral Xv(n) and Xv(k) signals, applying the horizontal signals simultaneously to a data buffer and to a spectrum domain converter block to yield, respectively, spectral Xh(n) and Xh(k) signals, detecting the angle of rotation, applying the angle of rotation and the Xv(k) and Xh(k) signals to a polarization rotation correction block to obtain polarization corrected frequency data, and applying the detected angle of rotation and the Xv(n) and Xh(n) signals to a polarization rotation correction block to obtain polarization corrected time data. | ||||||
| 127 | TRANSMISSION APPARATUS, TRANSMISSION METHOD AND TRANSMISSION SYSTEM | US13696522 | 2011-04-27 | US20130059549A1 | 2013-03-07 | Hideki Ogata |
| In order to improve the efficiency of removing a component of a signal different from a target received signal, a transmission apparatus includes: a reception means for receiving a first signal transmitted by a first transmission apparatus, and removing a component of a second signal transmitted by a second transmission apparatus, the second signal being received along with the first signal, using a third signal inputted from a third transmission apparatus receiving the second signal; a control means for setting a first modulation method based on the first signal, and generating first information, the first information being information including directions to change a modulation method of the first signal and a modulation method of the second signal to the first modulation method; and a transmission means for transmitting the first information to the first transmission apparatus. | ||||||
| 128 | Diversity antenna system and method utilizing a threshold value | US12815848 | 2010-06-15 | US08385868B2 | 2013-02-26 | Ming Lee; Wladimiro Villarroel; Kwan-ho Lee; Yasutaka Horiki |
| An antenna system for receiving an RF signal from a first antenna and a second antenna includes a phase shift circuit. The phase shift circuit shifts a phase of the RF signal from the second antenna by one of a plurality of possible phase shifts to produce a phase shifted signal. A combiner combines the RF signal from the first antenna and the phase shifted signal to produce a combined signal. A comparator circuit compares a signal quality of the combined signal with a minimum threshold value to determine if the signal quality of the combined signal is equal to or greater than the threshold value. The comparator circuit is in communicative control of the phase shift circuit and maintains the phase shift of the RF signal received by the second antenna in response to the signal quality of the combined signal being equal to or greater than the threshold value. | ||||||
| 129 | METHOD AND APPARATUS FOR ANTENNA RADIATION CROSS POLAR SUPPRESSION | US13429042 | 2012-03-23 | US20120244899A1 | 2012-09-27 | David Edwin Barker; David Sam Piazza; Stephen Thomas Newbold |
| Cross-polar discrimination (XPD) of a dual orthogonal cross-polarised antenna is maximized via a cross-coupling network between base station MIMO branches prior to connection to the base station antenna. In one embodiment, a cross coupling network combines each MIMO branch signal with an attenuated phase reversed (phase shifted) copy of the other MIMO branch signal. The amount of attenuation for each branch is equivalent to the cross polar suppression required for each antenna array. The cross-coupling can be applied at different stages of signal processing within a base station. | ||||||
| 130 | METHOD AND DEVICE FOR OPERATING A PRECODED MIMO SYSTEM | US13356441 | 2012-01-23 | US20120128044A1 | 2012-05-24 | Taeyoon Kim; Jayesh H. Kotecha |
| A method is provided for generating precoder data (600), comprising: obtaining transmit power data indicative of a transmit power of a plurality of multiple-input/multiple-output signals (610); obtaining signal quality data, the signal quality data including at least one measure of a quality of the plurality of multiple-input/multiple-output signals (620, 630); obtaining channel data with respect to a wireless channel, the channel data including a measure of respective channel parameters of each of a plurality of channel paths in the wireless channel (620, 630); constraining one or more system performance parameters (640); and determining first and second precoder diagonal values (wA and wB) based on the signal quality data, the transmit power data, the channel data, and the one or more constrained system performance parameters (650). | ||||||
| 131 | Communication Between Modems in XPIC Configuration For Wireless Applications | US13260606 | 2009-03-30 | US20120039372A1 | 2012-02-16 | Giovanni Milotta; Antonio Carugati |
| A radio communication network which comprises a plurality of radio links for communicating radio signals with orthogonal polarization. Each radio link comprises a vertical polarization communication device (11a) and a horizontal polarization communication device (11b) which share a local communication channel (11c). Each of these communication devices comprises at least one differential interface stage (21a, 21b, 31a, 31b) for communicating first data over the local communication channel (11c), based on a differential input. Each of these vertical and horizontal communication devices (11a, 11b) comprises means (27, 37) connected to the differential interface stages for communicating second data over the local communication channel by modulating a common mode of the differential interface stages. | ||||||
| 132 | WIRELESS COMMUNICATION APPARATUS, WIRELESS COMMUNICATION SYSTEM AND WIRELESS COMMUNICATION METHOD | US13141743 | 2010-01-06 | US20110261894A1 | 2011-10-27 | Qian Yu; Lei Huang; Masayuki Hoshino; Daichi Imamura |
| In a MIMO system using a cross-polarized antenna structure, even if no ideal XPD can be obtained, the interference between different polarized waves can be reduced to allow an effective precoding to be executed. When a MIMO communication is performed between a transmitter (250) and a receiver (260) each using a cross-polarized antenna structure, a channel estimating and precoding selection section (214) of the receiver (260) performs a channel estimation of MIMO channels from the transmitter to the receiver, decides a precoding matrix (P) of a projection matrix for mutually orthogonalizing or substantially orthogonalizing the channel response matrixes for respective different polarized waves, and feeds the determined precoding matrix (P) back to the transmitter (250). In the transmitter (250), a precoding processing section (208) applies the precoding matrix (P) to the spatial stream corresponding to one of the polarized waves to perform a precoding, thereby allowing the transmitter (250) to transmit the polarized waves with the orthogonality therebetween maintained. | ||||||
| 133 | Cross polarization interference canceling method and cross polarization interference canceling apparatus | US12088176 | 2006-10-18 | US07925236B2 | 2011-04-12 | Masahiro Kawai |
| A cross polarization interference canceling apparatus of the present invention includes: error detector 26 for extracting a difference between a demodulated signal that is the main polarization signal in which compensation for cross polarization interference has been made and the received signal which indicates an ideal state of the main polarization, and outputting an error signal that indicates the extracted difference; phase noise detector 27 for outputting a phase noise difference by comparing a cross polarization interference compensating signal that is the opposite polarization signal in which compensation for cross polarization interference has been made with the error signal; a control signal generator for generating a control signal corresponding to the phase noise difference; and phase rotator 18′ disposed prior to, or posterior to, a cross polarization interference canceller for generating the cross polarization interference compensating signal, for controlling the phase of the cross polarization interference compensating signal in such a direction as to suppress the phase noise difference, in response to the input of the control signal. | ||||||
| 134 | CROSS POLARIZATION INTERFERENCE CANCELING METHOD AND CROSS POLARIZATION INTERFERENCE CANCELING APPARATUS | US12088176 | 2006-10-18 | US20090143042A1 | 2009-06-04 | Masahiro Kawai |
| A cross polarization interference canceling apparatus of the present invention includes: error detector 26 for extracting a difference between a demodulated signal that is the main polarization signal in which compensation for cross polarization interference has been made and the received signal which indicates an ideal state of the main polarization, and outputting an error signal that indicates the extracted difference; phase noise detector 27 for outputting a phase noise difference by comparing a cross polarization interference compensating signal that is the opposite polarization signal in which compensation for cross polarization interference has been made with the error signal; a control signal generator for generating a control signal corresponding to the phase noise difference; and phase rotator 18′ disposed prior to, or posterior to, a cross polarization interference canceller for generating the cross polarization interference compensating signal, for controlling the phase of the cross polarization interference compensating signal in such a direction as to suppress the phase noise difference, in response to the input of the control signal. | ||||||
| 135 | Method for Polarization Correction in User Equipment | US12088652 | 2006-09-29 | US20080293362A1 | 2008-11-27 | Ulf Lindgren |
| A method and device for compensation of received signal components at a user equipment (UE) used for receiving signal components from a radio base station (RBS). The signal components have at least a first and a second polarization orientation, respectively. The intended reception of the signal component (Yh(n)) having the first polarization deviates from the polarization orientation of the transmitted signal component (Xh(n)) having the first polarization by a first angle (φ), and the intended reception of the signal component (Yv(n)) having the second polarization deviates from the polarization orientation of the transmitted signal component (xv(n)) having the second polarization by a second angle (β). The method comprises the steps: determining the correlation values (Ryw, Ryvy, Ryyv, Ryyy) for the received signals (Yh, Yv) at a first time (k) and a second time (m); using these values to determine the deviation angles (φ, θ) performing said compensation using the deviation angles (φ, θ). | ||||||
| 136 | Opposite polarization interference cancellation in satellite communication | US09423868 | 1999-11-15 | US06597750B1 | 2003-07-22 | Paul Gothard Knutson; Kumar Ramaswamy; David Lowell McNeely |
| A system for receiving a plurality of broadcast channels transmitted with different polarizations includes a first demodulator for demodulating a first channel having a first polarization to produce a first demodulated channel signal, and a second demodulator for demodulating a second channel having a second polarization, opposite to the first polarization, to produce a second demodulated channel signal. An adaptive interference cancellation network, coupled to the first and second demodulators, cancels interference, derived from the second channel, in the first demodulated channel signal to produce a received signal. | ||||||
| 137 | Cross polarization interference compensating device comprising decision feedback cross polarization interference cancellers | US358602 | 1994-12-14 | US5432522A | 1995-07-11 | Yuzo Kurokami |
| On receiving a symbol sequence carried by a first-polarization and a second-polarization signal of two orthogonally polarized signals and in order to cancel a cross polarization interference (XPI) component which leaks from the second-polarization signal into the first-polarization signal, a first decision feedback XPI canceller (43) is supplied with a before processed signal derived from the second-polarization signal and with a decided signal which is produced by a decision circuit (22) and which represents the symbol sequence carried by the second-polarization signal with an intersymbol interference component and another XPI component cancelled from the before processed signal. Another decision feedback XPI canceller (44) is similarly operable. Preferably, a first decision feedback equalizer (41) is supplied with another before processed signal derived from the first-polarization signal and with another decided signal which is produced by another decision circuit (21) and which represents the symbol sequence carried by the first-polarized signal with another intersymbol interference component and the first-mentioned XPI component cancelled from the last-mentioned before processed signal. A second decision feedback equalizer (42) is similarly used. Alternatively, a delay element is used instead of each decision feedback equalizer if the intersymbol interference components are negligible. | ||||||
| 138 | Cross polarization interference canceller | US980662 | 1992-11-24 | US5383224A | 1995-01-17 | Shoichi Mizoguchi |
| In a cross polarization interference canceller for use in digital radio communications, a signal processing circuit monitors whether numbers of word sync signals and error pulses obtained in error correction decoding exceed specified values, and outputs reset signal RS1 when an abnormality is detected. A signal level detection circuit outputs reset signal RS2 when it is detected that a level of a different polarization side baseband signal from a demodulator is lower than specified. A logical sum RS3 of reset signals RS1 and RS2 is supplied to a cross polarization interference cancellation device, which may have a transversal filter. When the word is not synchronized or the number of error pulses generated in error correcting decoding exceeds the specified value, the self-polarization side can be protected from unnecessary interference and disturbance and the self-polarization side data can be protected from disturbance even though an abrupt abnormality occurs in different polarization signals. | ||||||
| 139 | Dual polarization transmission system | US584012 | 1990-09-18 | US5075697A | 1991-12-24 | Yutaka Koizumi; Shigeki Maeda |
| A dual polarization transmission system for transmitting digital modulated signal each having a particular bandwidth by use of two polarized waves which have the same center frequency and are orthogonal to each other. The receiver side of the system demodulates radio frequency signals sent by a horizontally and a vertically polarized wave and coming in through a receiving antenna into IF signals. From the received signal of one polarization, an interference component of the other polarization generated on the basis of the cross-polar IF signal or demodulated signal is removed. | ||||||
| 140 | Cross-polarization interference cancellation system capable of stably carrying out operation | US558754 | 1990-07-27 | US5023620A | 1991-06-11 | Toru Matsuura |
| In a cross-polarization interference cancellation system operable in response to desired and undesired or interference source signals which are obtained from polarized waves having planes of polarization orthogonal to each other and which are produced in accordance with clock signals having a predetermined clock frequency, an interference signal is included in the desired signal and is derived from the interference source signal to be removed from the desired signal by the use of an interference canceller and to be produced as an interference free signal. The interference free signal is demodulated into demodulated signals, error signals, and quadrant detection signals by a demodulator unit. In this event, the quadrant detection signals alone are stably demodulated by the use of specific clock signals which are sent through a frequency doubler operable to double the predetermined clock frequency of the clock signals. The interference canceller comprises a transversal filter and a control signal generator for supplying the transversal filter with control signals stably produced by the control signal generator. As a result, the interference canceller is stably operated in response to the control signals. | ||||||
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