RU2002103215A - A method of forming a radiation pattern of an adaptive antenna array of a base station and a device for its implementation (options) - Google Patents

Claims (8)

1. The method of forming the radiation pattern of the adaptive antenna array of the base station, in which the common pilot signal is transmitted from one of the elements of the antenna array, and the information signal to each subscriber from all elements of the antenna array, which consists in the fact that upon receiving the subscriber signal form complex correlation responses the pilot signal of the elements of the antenna array, form the complex weight coefficients of the elements of the adaptive antenna array in the return channel, for each of L different directions of the angular region form the decisive function, determine the direction of the maximum of the decisive function, form an estimate of the average angle of arrival of the signal, taking into account the geometry of the antenna array determine the phase coefficients of the elements of the antenna array using the generated estimate of the average angle of arrival, characterized in that before generating complex correlation responses of the pilot signal elements of the antenna array for each subscriber search for the subscriber signal, finding the temporary position of the beam signals, select the beam, sig Al of which is maximum in power, a sequence of estimates of the angle of arrival of the signal is formed, and for the formation of each estimate of the angle of arrival of the signal after the formation of the complex correlation responses of the pilot signal of the antenna array elements for each of the L different directions of the investigated angular region, complex correlation responses of the pilot signal to the output of the antenna array, summing up the products of the complex correlation responses of the pilot signal of the elements of the antenna array to their corresponding set the respective coefficients of each direction, form the modules of the complex correlation responses of the pilot signal at the output of the antenna array for L different directions and determine the maximum of them, form the normalized modules of the complex correlation responses of the pilot signal at the output of the antenna array for L different directions, finding the ratios of the modules of complex correlation responses pilot signal at the output of the antenna array for L different directions to the maximum module, after the formation of complex weights of antenna array elements in the return channel for each of the L different directions of the studied angular region form the antenna array radiation pattern in the return channel, determine the maximum of the generated antenna array radiation pattern in the return channel, and normalize the antenna array radiation pattern in the return channel for L of different directions, finding the ratio of the radiation pattern values to the maximum value, a decisive function for each about from L different directions of the studied angular region are formed by weighted summing of the normalized module of the complex correlation response of the pilot signal at the output of the antenna array and the normalized radiation pattern of the antenna array in the return channel, when determining the direction of the maximum of the decision function, the signal arrival angle is estimated as the direction the maximum of the decisive function, the sequence of generated estimates of the angle of arrival of the signal is grouped into blocks, each of which contains lives M estimates of the angle of arrival of the signal, form a sequence of distribution vectors of estimates of the angle of arrival of the signal of the blocks, and for each block, according to M formed estimates of the angle of arrival of the signal of the block, form a distribution vector of the estimates of the angle of arrival of the signal of the block L, each element of which corresponds to one of the L directions of the studied the angular region and is equal to the number of estimates of the angle of arrival of the signal in a given direction, from the sequence of distribution vectors of estimates of the angle of arrival of the signal of the blocks form the sequence the averaged distribution vectors of the estimates of the angle of arrival of the signal using a sliding window, for each averaged distribution vector of the estimates of the angle of arrival of the signal, estimates of the lower and upper boundaries of the angular region of the signal are determined, an estimate of the average angle of arrival is formed from the estimates of the lower and upper boundaries of the angular region of the signal, after determining the phase coefficients of the elements of the antenna array form a correlation matrix of signals of the elements of the antenna array according to the found estimates of the lower and upper boundaries the main region of the signal, the Cholesky transformation of the formed correlation matrix is performed, obtaining the lower triangular matrix, the ratio of the amplitude coefficients of the antenna array elements to the amplitude coefficient of the antenna array element from which the pilot signal is transmitted using the obtained lower triangular matrix and phase coefficients of the antenna array is determined by the found ratio, taking into account the number of elements of the antenna array, determine the normalization coefficient, determine the amplitude coefficient entrances of the elements of the antenna array, multiplying the normalization coefficient by the ratio of the amplitude coefficients of the elements of the antenna array to the amplitude coefficient of the element of the antenna array from which the pilot signal is transmitted, the generated amplitude and phase coefficients of the elements of the antenna array are used to transmit the information signal to the subscriber. 2. The method according to claim 1, characterized in that to evaluate the lower and upper boundaries of the angular region of the signal, determine the maximum element of the averaged distribution vector of estimates of the angle of arrival of the signal, determine the lower and upper elements as the boundaries of the group of elements of the averaged distribution vector of estimates of the angle of arrival of the signal, this group of elements includes the maximum element of the averaged distribution vector of estimates of the angle of arrival of the signal, and the elements of the group exceed the threshold, however, on each side of the maximum element Steam, single threshold not exceeding the threshold, as well as one group threshold not exceeding two or three adjacent elements, determine the sum of the elements of the averaged distribution vector of estimates of the angle of arrival of the signal located below the lower element, and the sum of the elements of the averaged distribution vector of estimates of the angle of arrival of the signal located above the upper element , form a correction correction for the lower element, depending on the sum of the elements of the averaged distribution vector of the estimates of the angle of arrival of the signal, located values below the lower element, and the correction correction for the upper element, depending on the sum of the elements of the averaged distribution vector of estimates of the angle of arrival of the signal located above the upper element, determine the correction value for the lower and upper elements, depending on the position of the maximum element of the averaged distribution vector of the estimates of the angle of arrival of the signal , determine the estimate of the lower boundary of the angular region of the signal as the difference of the angular coordinate corresponding to the lower element, and the amount of correction Application for the bottom element and the correction value, determining an estimate of the top signal angular area boundaries as the sum of the angle coordinate corresponding to the top element, correcting amendment for the top element and correction value. 3. The method according to claim 1, characterized in that the estimate of the average angle of arrival is formed as half the estimates of the lower and upper boundaries of the angular region of the signal. 4. The method according to claim 1, characterized in that the ratio of the amplitude coefficients of the elements of the antenna array to the amplitude coefficient of the element of the antenna array from which the pilot signal is transmitted is equal to each other, and this ratio is determined as the maximum value from the interval from 0 to 1, for which the ratio of the average powers of the statistically incoherent and statistically coherent terms of the model of the information signal received by the subscriber does not exceed a predetermined value. 5. The method of forming the radiation pattern of the adaptive antenna array of the base station, which consists in the fact that when receiving the subscriber’s signal, complex correlation responses of the pilot signal of the elements of the antenna array are formed, complex weight coefficients of the elements of the adaptive antenna array in the return channel are generated for each of L different directions the investigated angular region form the decisive function, determine the direction of the maximum decisive function, forming an estimate of the average angle of arrival of the signal, taking into account Antenna array measurements determine the phase coefficients of the antenna array elements using the generated estimate of the average angle of arrival, characterized in that before generating complex correlation responses of the pilot signal of the antenna array elements for each subscriber, a subscriber signal is searched for, finding the temporal positions of the beam signals, a beam is selected, a signal which is maximum in power, an estimate of the average angle of arrival of the subscriber signal is generated periodically, for which, after the formation of complex correlations The complex pilot correlation responses of the antenna signal elements in the return channel for each of L different directions of the investigated angular region form the complex correlation responses of the pilot signal at the output of the antenna array, summing the products of the complex correlation responses of the pilot signal of the antenna array elements to the corresponding complex coefficients of each direction , form the modules of the complex correlation responses of the pilot signal at the output of the antenna array for L different directions, form the total the correlation response of the pilot signal at the output of the antenna array for L different directions, summing the modules of the complex correlation responses of the pilot signal at the output of the antenna array for L different directions, and determine the maximum of them, form the normalized total correlation responses of the pilot signal at the output of the antenna array for L different directions, finding the ratio of the total correlation responses of the pilot signal at the output of the antenna array for L different directions to the maximum total correlation response, after the formation of the complex weight coefficients of the elements of the antenna array in the return channel for each of the L different directions of the studied angular region, the values of the antenna array pattern in the return channel are determined, the maximum of the generated antenna array radiation pattern values in the return channel are determined, normalized values of the diagram are formed directivity of the antenna array in the return channel for L different directions, finding the ratio of the values of the diagram for example In relation to the maximum value, the decisive function for each of the L different directions of the studied angular region is formed by weighting the normalized total correlation response of the pilot signal at the output of the antenna array and the normalized antenna radiation pattern in the return channel, after forming the average signal arrival angle and the phase coefficients of the elements of the antenna array set the amplitude coefficients of the elements of the antenna array equal to each other, the amplitude and phase coefficients of the elements of the antenna array are used to transmit a signal to the subscriber. 6. The method according to claim 5, characterized in that when summing the modules of the complex correlation responses of the pilot signal at the output of the antenna array for L different directions, the number of terms is fixed or selected adaptively depending on the estimate of the signal fading frequency. 7. A device for generating a radiation pattern of an adaptive antenna array of a base station, comprising N correlators, a reference signal generator, a block for estimating the angle of arrival of the signal, a block for generating a vector of weight coefficients of the antenna array in the return channel, and a block for generating a vector of weight coefficients of the antenna array in the forward channel, the first the correlator inputs are signal and connected to the device inputs, the second correlator inputs are reference and connected to the reference output of the reference generator ignala, characterized in that in addition L blocks of calculating the decisive direction function are introduced, each of which contains N-1 multipliers, a first adder, a module calculating unit, a complex directional coefficient block, and a unit for calculating discrete values of the antenna array radiation pattern in the reverse channel, and the search block, the control block, the first and second normalization blocks, the second adder, the scaling block, the block for generating the distribution vector of the estimates of the angle of arrival of the signal, the block for generating an averaged of the distribution vector of estimates of the angle of arrival of the signal, the analysis unit of the averaged distribution vector of estimates of the angle of arrival of the signal, and the first input of the search unit is connected to the first input of the device, the second input of the search unit is controllable and connected to the output of the control unit, the output of the search unit is the output of the decisive search function and connected to the input of the control unit, the input of the reference signal generator is controllable and connected to the output of the control unit that provides synchronous operation of the device blocks, the first the N-1 passages of the multipliers and the first input of the first adder are the first inputs of the block for calculating the directional direction function and are connected to the outputs of the corresponding correlators, which form at these outputs the correlation responses of the pilot signal of the antenna array elements, the outputs of the multipliers are connected to the inputs of the first adder, starting from the second in N, the output of the first adder is the output of the complex correlation response of the pilot signal of this direction at the output of the antenna array and is connected to the input of the calculation unit a module whose output is the output of the complex correlation response module of a pilot signal of a given direction at the output of the antenna array and the first output of each calculation unit for the directional direction function and is connected to the corresponding input of the first normalization unit, the first input of the calculation unit of the discrete values of the antenna array radiation pattern in the return channel is the second input of each block for calculating the decisive direction function and is connected to the output of the antenna weighting vector block the lattices in the return channel, which generates the weight coefficients of the antenna array elements in the return channel, the signal inputs of the vector array of the antenna array weight coefficients in the return channel are connected to the device inputs, the second input of the discrete antenna beam calculation unit in the return channel, and the second inputs N-1 multipliers are combined and connected to the output of the block of complex directional coefficients, which is the output of the complex coefficients of this direction I, the output of the unit for calculating discrete values of the antenna array radiation pattern in the return channel, which is the second output of the calculation unit for the decisive direction function and the output of the antenna array radiation pattern in the return channel of this direction, is connected to the corresponding input of the second normalization unit, the output of the first normalization unit, which is the output of the normalized modules of the complex correlation responses of the pilot signal at the output of the antenna array of all L directions, is connected to the first input the house of the second adder, the output of the second normalization block is the output of the normalized antenna array radiation pattern in the return channel of all L directions and is connected to the input of the scaling unit, the output of the scaling unit is the output of the weighted normalized antenna array radiation pattern in the reverse channel for L directions and is connected to the second input of the second adder, the output of the second adder is the output of the values of the decisive function for L directions and is connected to the input of the estimator and the angle of arrival of the signal, the output of which is the output of estimating the average angle of arrival of the signal and is connected to the input of the vector distribution unit for estimating the signal arrival angle, forming at the output a sequence of distribution vectors of estimates of the angle of arrival of the signal, the output of the generating unit of the distribution vector of estimating the angle of arrival of the signal is connected to the first the input unit of the formation of the averaged distribution vector of estimates of the angle of arrival of the signal, the second input of which is controllable and connected to the output of the control unit the output of the formation unit of the averaged distribution vector of estimates of the angle of arrival of the signal is the output of the sequence of averaged distribution vectors of estimates of the angle of arrival of the signal, and is connected to the input of the analysis unit of the averaged distribution vector of estimates of the angle of arrival of the signal, forming at its outputs estimates of the upper and lower boundaries of the angular region of the signal, the outputs of the analysis unit of the averaged distribution vector of estimates of the angle of arrival of the signal are connected to the corresponding inputs of the unit for generating the weight vector the antenna array coefficients in the forward channel, the outputs of the vector array weighting unit of the antenna array in the forward channel are the outputs of the amplitude and phase coefficients of the antenna array elements. 8. A device for generating a radiation pattern of an adaptive antenna array of a base station, comprising N correlators, a reference signal generator, a block for estimating the angle of arrival of the signal, a block for generating a vector of weight coefficients of the antenna array in the return channel, and a block for generating a vector of weight coefficients of the antenna array in the forward channel, the first the correlator inputs are signal and connected to the device inputs, the second correlator inputs are reference and connected to the reference output of the reference generator ignala, characterized in that L blocks of calculating the directional directional decision function are additionally introduced, each of which contains N-1 multipliers, a first adder, a module calculation unit, an adder with a reset, a complex directional coefficient block and a unit for calculating discrete values of the antenna array radiation pattern channel, as well as the search block, the control block, the first and second normalization blocks, the second adder, the scaling block, the first input of the search block connected to the first input of the device, the second in One of the search unit is controllable and connected to the output of the control unit, the output of the search unit is the output of the decisive search function and is connected to the input of the control unit, the input of the reference signal generator is controllable and connected to the output of the control unit that provides synchronous operation of the device blocks, the first inputs are N- 1 multipliers and the first input of the first adder are the first inputs of the block for calculating the decisive direction function and are connected to the outputs of the corresponding correlators forming at these outputs the correlation responses of the pilot signal of the elements of the antenna array, the outputs of the multipliers are connected to the inputs of the first adder, starting from the second to N, the output of the first adder is the output of the complex correlation response of the pilot signal of this direction at the output of the antenna array and connected to the input of the module calculation unit, the output of which is the output of the complex correlation response module of the pilot signal of a given direction at the output of the antenna array and is connected to the first input of the adder with a reset, the second input is Horn is the input of the reset signal and is connected to the output of the control unit, the output of the adder with the reset is the output of the total correlation response of the pilot signal of a given direction at the output of the antenna array and the first output of each calculation unit of the decisive direction function and is connected to the corresponding input of the first normalization block, the first input the unit for calculating discrete values of the antenna array radiation pattern in the return channel is the second input of each unit for calculating the decisive direction function and with the output of the unit for generating the vector of weighting coefficients of the antenna array in the return channel, generating at the output the weighting coefficients of elements of the antenna array in the return channel, the signal inputs of the unit for generating the vector of weighting coefficients of the antenna array in the return channel are connected to the inputs of the device, the second input of the block for calculating discrete values of the radiation pattern the antenna array in the return channel and the second inputs of the N-1 multipliers are combined and connected to the output of the block of complex direction coefficients, which is the output of the complex coefficients of a given direction, the output of the unit for calculating discrete values of the antenna pattern in the return channel, which is the second output of the calculation unit for the decisive direction function and the output of the antenna pattern in the return channel of this direction, is connected to the corresponding input of the second normalization unit , the output of the first normalization block, which is the output of the normalized total modules of complex correlation responses the pilot of the signal at the output of the antenna array of all L directions, connected to the first input of the second adder, the output of the second normalization block is the output of the normalized values of the antenna array pattern in the return channel of all L directions and connected to the input of the scaling unit, the output of the scaling unit is the output of weighted normalized values the antenna array radiation pattern in the return channel for L directions and is connected to the second input of the second adder, the output of the second adder is one of the values of the decisive function for L directions and is connected to the input of the block for estimating the angle of arrival of the signal, the output of which is the output of estimating the average angle of arrival of the signal and is connected to the input of the block for generating the vector of weight coefficients of the antenna array in the forward channel, the outputs of the block for generating the vector of weight coefficients of the antenna array in direct channel are the outputs of the amplitude and phase coefficients of the elements of the antenna array.