RU2137314C1 - Method of switching of base station in cellular radio communication systems with code separation of channels, method of evaluation of frequency of signal fading in propagation medium in radio communication systems with closed loop controlling power of mobile station and receiving equipment of base station ( versions ) - Google Patents

Abstract

FIELD: radio engineering, specifically, cellular systems with code separation of channels using relay transfer to ensure uninterrupted communication of mobile station with base one. SUBSTANCE: novelty of method of switching of base station in cellular radio communication systems with code separation of channels lies in determination of moments of start and finish of relay transfer when adaptive smooth evaluations of level of signal in backward channel are used. Evaluation of frequency of fast fading in communication channel is employed to tune parameters of smoothing. Novelty of method of evaluation of frequency of signal fading in propagation medium in radio communication systems with closed loop controlling power of mobile station consists in reconstruction of monotony of signal envelope before frequency analysis when receiving signal of backward channel with usage of initial sequences of commands for power control. Receiving equipment of base station is developed to realize above- mentioned methods. EFFECT: enhanced quality and reliability of communication, enlarged system capacity and improved optimality in distribution of system resources thanks to decreased influence of fast fading in channel on decision making on relay transfer. 4 cl, 12 dwg

Description

 The invention relates to the field of radio engineering, in particular to cellular systems with code division multiplexing, using relay transmission methods to ensure continuity of communication between the mobile station and the base station.

A necessary condition for the normal functioning of modern cellular mobile radio systems is to ensure continuity of the communication session when moving a mobile station from the service area of one base station to the service area of another base station. The procedure for switching a user channel (traffic) from one base station to another when moving a mobile station is usually called a relay transmission. A variation of this procedure, when before breaking the connection between the mobile station and the first base station, an alternative communication channel is first established through the second base station, through which the same information is transmitted both in the forward and reverse directions as on the first channel, called soft relay transmission . Soft handoff is used in digital systems in which a mobile station is capable of simultaneously receiving an information signal from more than one base station simultaneously, for example, in code division multiplexing (CDMA) systems. The soft transfer principle is illustrated in FIG. 1 where
BS1 and BS2 are the base stations of the first and second cells, respectively; BS1.1 and BS1.2 are the sectors of base station 1, respectively;
BS2.1 sector of base station 2;
a) the trajectory of the mobile station;
b), c) and d), respectively, diagrams of average quality of communication with sectors BS1.1, BS1.2 and BS2.1;
t1 is the time during which the mobile station serves BS1.1,
t2 is the time during which the mobile station serves BS1.2,
t3 is the time during which the mobile station serves BS2.1.

 The main task in the implementation of relay transmission algorithms is to determine the specific moment for the start of the transmission procedure. Existing methods are based on various criteria: comparing the distance from the mobile station to the current and alternative base stations, comparing the quality of communication channels between the mobile and current and alternative base stations and others. Methods based on comparing the quality of communication channels can be divided into two groups: with measurements performed by base stations and with measurements performed by both base and mobile stations. The first group of methods is used in most modern mobile radio communication systems. The second group is used in code division multiplexing (CDMA) systems.

 In an advanced mobile telephone system (AMPS) at the base station serving the mobile station, the signal level in the reverse channel is measured and the results are reported to the system controller. When the signal level drops below a certain value, the system controller tells the base stations adjacent to the given one to start measuring the signal level from this mobile station. The base station that has registered the highest signal level is considered candidate for serving this mobile station. Subsequently, the system controller continues to compare the signal strength measurements of the given mobile station made by the current base station and the candidate candidate base station found. When a certain relationship is reached between the measurement results of these two base stations, the system controller tells the first base station to stop receiving and transmitting signals for this mobile station, tells the second base station to start receiving and transmitting signals from this mobile station, and tells the mobile station to start receiving and signaling through a second base station. The described procedure is a hard relay transmission, i.e., the connection with the mobile station is first disconnected, and then restored through another base station.

 This technology has a number of significant disadvantages. Firstly, in the process of relay transmission there is a short-term disconnection of communication with this mobile station. Secondly, due to the presence of fast Rayleigh fading of the radio signal, the mobile station may erroneously switch back to serving the first base station and back to serving the second base station - the so-called ping-pong effect.

 In a system with code division multiplexing (CDMA), for example, according to the IS-95 standard [1, Mobile and base station compatibility standard for dual-mode cellular wideband systems with spreading spectrum. TIA / EIA / IS-95-A, may 1995. Telecommunications Industry Association], in addition to the above, another method is also used to determine when a relay transmission begins. In the CDMA system, each base station transmits its own pilot channel, which from the point of view of the mobile station allows neighboring base stations to differ from each other. At the mobile station, the relative level of the pilot signals surrounding its base stations is measured, a list of which the mobile station receives from the current base station. The measurement results for each pilot signal at the mobile station are compared with predetermined threshold values (a set of threshold values) received from the base stations, and the comparison results are reported to the base station. Based on this information, the base station or system controller may decide to start (end) the relay transmission of this mobile station. In the process of relay transmission, the channel (traffic) for a given mobile station is broadcast simultaneously through two or more base stations, and the mobile station, depending on its characteristics, selects the best received signal or combines several received signals. In the return channel, the system controller selects the best signal received by the base stations from the mobile station.

A known system and method for providing soft switching in a cellular communication system with code division multiplexing (CDMA) [2, US patent N 5101501, MKI ⁵ H 04 Q 7/00, H 04 M 11/00], in which each mobile station is measured the relative level of the pilot signals surrounding its base stations, a list of which at the mobile station is received from the current base station. The measurement results for each pilot signal at the mobile station are compared with a predetermined threshold value received from the base stations, and the comparison results are reported to the base station. Based on this information, the base station or system controller makes a decision about the start (end) of the relay transmission of this mobile station. In the process of relay transmission, the channel (traffic) for a given mobile station is broadcast simultaneously through two or more base stations, and at the mobile station, depending on its characteristics, the best received signal is selected or several received signals are combined. In the return channel, the system controller selects the best of the decoded signals received by the base stations from the mobile station, or performs a combination of undecoded signals.

 The disadvantage of this invention is that in the conditions of fast fading in the channel, this system and the proposed method do not accurately determine the start and end of the relay transmission. This leads to difficulties in optimally adjusting the duration of the soft handoff process depending on the specific situation and the parameters of the mobile and base stations, which negatively affects the quality of communication and system capacity. In addition, under certain conditions, the ping-pong effect arises, which leads to a non-optimal distribution of system resources.

The closest technical solution to the claimed method and device for its implementation is the invention [3, US patent N 5345467, MKI ⁵ H 04 L 27/30 "Method and device for handoff in the CDMA system"], which use N base stations of the cellular system radio communications so that the mobile station at any point in space can establish communication with at least one base station, namely, that N base stations are combined into logical groups so that all M base stations through which The mobile station performs duplex communication, and to the neighboring group, all K base stations directly adjacent to the base stations of the active group evaluate the parameters of the communication channels with the mobile station through each of the M base stations of the active group and each of the K base stations of the neighboring group, compare with a given threshold value, in this case, if the channel parameter estimate of any of the K base stations of the neighboring group exceeds a predetermined threshold value, then such a base station is transferred to the active group and formed receive and transmit signal channels for the mobile station, if the channel parameter estimate of any of the M base stations of the active group is below a predetermined threshold, then when M is greater than 1, such a base station is excluded from the active set, while the receive channels are deleted on it and signal transmission. This method uses parameters such as signal propagation delay, relative signal strength, and combinations thereof.

 The disadvantage of this invention is that this device and the proposed method do not allow to accurately determine the start and end of the relay transmission. This is due to the fact that the cellular system with code division multiplexing has sectorized cells in which there is not always an unambiguous correlation between the change in the propagation delay of the signal and the change in the quality of communication channels. Therefore, when using time parameters, such as signal propagation delay, the distance between the base and mobile stations, to make a decision on handoff, it leads to suboptimality in terms of reception quality, i.e. if the mobile station receives a signal from two base stations with the same delay, then the average levels of these signals can vary significantly.

 In addition, a decision on handoff using a comparison of pilot levels is unreliable due to channel fading. The visibility of this drawback is illustrated in FIG. 2. As a result, this makes it difficult to optimally adjust the duration of the soft handoff process, depending on the specific situation and the parameters of the mobile and base stations, which negatively affects the quality of communication and system capacity. In addition, under certain conditions, the ping-pong effect occurs, which leads to a non-optimal distribution of system resources.

The signals in the communication channel in systems with mobile stations are subject to fading, which occupy different frequency ranges and depend mainly on the speed of the mobile station. A qualitative example of the spectral composition of such fading is shown in FIG. 3a, where
a - spectrum of fast fading (multipath interference);
b is the fundamental frequency of fast fading;
c - spectrum of slow fading (terrain, shading by large objects);
d - slow level changes from the antenna pattern;
e - slow level changes due to radial attenuation.

 A view of the corresponding signal in the time domain is shown in FIG. 3c.

 Fading caused by components c, d, e, is slow and leads to long-term changes in the quality of communication channels and may be a prerequisite for switching this mobile station to service another base station. At the same time, fast fading in the communication channel caused by multipath interference causes short-term attenuation of the signal, which is not the basis for starting a relay transmission, but lead to errors in deciding on a relay transmission, unless special measures are taken.

 For accurate determination of the start and end times of a relay transmission and the elimination of erroneous decisions, it is necessary to reduce the effect of fast fading on the result of measuring channel quality. To reduce the depth of fading, you can use some kind of smoothing. But at the same time, for smoothing efficiency, it is necessary to have information about the main fading frequency, which is directly proportional to the speed of the mobile station.

 Estimating the frequency of fading in the communication channel in systems with a closed loop power control loop of the mobile station, which is mandatory for systems with code division multiplexing (CDMA) especially at low speeds, is difficult, since the spectrum of fading is masked by power control. This is illustrated in FIG. 3b and 3d.

 There are various methods for assessing the spectral characteristics of a signal, for example, a fast Fourier transform, which makes it possible to obtain an estimate of the spectrum from a block of input discrete data [4, Ed. K.A. Samoilo. Radio circuits and signals. "Radio and communication." M. - 1982, p. 267 - 268], as well as other methods described in [5, S.L. Marpleml. Ed. I.S. Ryzhak. Digital spectral analysis and its application. M. - "The World". 1990].

 To estimate the fading frequency, the above methods for evaluating the spectral characteristics of a signal can be used, but in systems with closed power control, their use leads to a large error. This is because the power adjustment masks the spectrum of fading, which is clearly illustrated in Fig.3. Moreover, the authors do not change the sequence of operations for evaluating the spectral characteristics of the signal, but convert the signal, which is then subjected to spectral analysis.

Based on available technical sources, the authors were not able to find a closer technical solution that could be chosen as a prototype for a method for estimating the frequency of signal fading in a propagation medium in radio communication systems with a closed loop for adjusting the power of a mobile station, therefore, the same technical solution was taken as a prototype as for the method of switching the base station in cellular radio communication systems [3, US patent N 5345467, MKI ⁵ H 04 L 27/30 "Method and device for handoff in the CDMA system"]. Moreover, the method for estimating the frequency of signal fading in the propagation medium in radio systems with a closed loop power control of the mobile station was created to implement the method of switching the base station in CDMA cellular radio communication systems, but this does not exclude the possibility of using it in other communication systems. Therefore, it is highlighted in an independent claim. In the prototype, the relative level of the received signal is measured at each of the M base stations of the active group and at each of the K base stations of the neighboring group. But they measure this parameter for other purposes, for example, to measure the level of the received signal, for diversity summation and power control, as well as for system statistics about the quality of communication.

 In the description and claims of this invention, it was not found that measuring the relative level of the received signal at each of the M base stations of the active group and at each of the K base stations of the neighboring group is used precisely for estimating the frequency of signal fading. However, given the fact that this feature is still present in the prototype, the authors took it to the restrictive part.

 The problem to be solved by the claimed group of inventions is a method of switching a base station in cellular systems with code division multiplexing, a method for estimating the frequency of fading of a signal in a radio communication system with a closed loop for adjusting the power of a mobile station and receiving equipment of a base station (options), this is an improvement in the quality and reliability of communication, system capacity and optimal distribution of system resources by reducing the influence of fast fading in the channel on the decision on handoff.

This task is achieved by the fact that:
Firstly, in a method for switching a base station in code division multiplex cellular radio systems, in which N base stations of a cellular radio communication system are used so that a mobile station at any point in space can communicate with at least one base station, comprising that combine N base stations into logical groups so that the active group includes all base stations through which the mobile station performs duplex communication, and the neighboring group includes all the base Stations directly adjacent to the base stations of the active group evaluate the parameters of the communication channels with the mobile station through each of the M base stations of the active group and each of the K base stations of the neighboring group, and compare with a predetermined threshold, if the channel parameters are estimated or from K base stations of a neighboring group exceeds a predetermined threshold value, then such a base station is transferred to the active group and channels for receiving and transmitting a signal for the mobile station are formed on it, if the parameters are estimated of a channel of any of the M base stations of the active group is below a predetermined threshold, then, when M is greater than 1, such a base station is excluded from the active set, while the channels of signal reception and transmission are deleted on it, the following sequence of operations is additionally introduced:
- search for the signal of the mobile station at each of the K base stations of the neighboring group and evaluate its level,
- allocate L channels from the K channels of the neighboring group, in which the signal level estimates exceed a predetermined threshold value,
- evaluate the frequency of fading of the signal from the mobile station in the propagation medium,
- calculate a smoothed estimate of the signal level from the mobile station in each of the L channels of the neighboring group, and in each of the M channels of the active group by adaptively smoothing the sequence of estimates of the level of the received signal, using information on the basic frequency of signal fading for adaptation, thus obtaining M plus L smoothed ratings,
- the obtained smoothed level estimates are compared with each other or with switching thresholds and, based on the results of the comparison, decide on the composition of the active group.

Secondly, in a method for estimating the frequency of fading of a signal in a propagation medium in radio systems with a closed loop of power control of a mobile station, in which the quality of communication at each of the M base stations of the active group is evaluated with an interval equal to the interval between power control commands and transmitted to the mobile station commands power control, and if the assessment of the quality of communication at the base station exceeds a predetermined threshold value, then form a command to reduce power if the assessment of the quality of communication on ba of the new station is less than the specified threshold value, a command to increase power is generated, a power control command is allocated from each of the M received signals from the mobile station, and the power is controlled so that if all the received commands require an increase in power, then increase the power by A times if at least one command requires a decrease in power, it is reduced by a factor of B, where A is the specified step of increasing power, B is the specified step of decreasing power, which consists in measuring the relative level of the received signal on each of the K base stations neighboring group, additionally introduced following sequence of operations:
- measure the relative level of the received signal at each L of the K base stations of the neighboring group, in which the signal level estimates exceed a predetermined threshold value, with an interval equal to the interval between the power adjustment commands, form M plus L sample sequences,
- remember at each of the M base stations of the active group the power control commands transmitted to the mobile station
- form a sequence of coefficients, using the stored commands in such a way that if all M teams require an increase in power, then form a coefficient equal to 1 / A, if at least one team requires a decrease in power, then form a coefficient equal to B,
- correct the sequence of samples of the relative level of the received signal at each of the M base stations of the active group and at each of the L base stations of the neighboring group by multiplying the elements of the original sequences by the corresponding elements of the obtained sequence of coefficients,
- form estimates of the main frequency of signal fading by frequency analysis of the received corrected sequences at each of the M base stations of the active group and at each of the L base stations of the neighboring group, thus forming M plus L ratings,
- calculate the average estimate of the main frequency of signal fading in the propagation medium for a given mobile station, using all the estimates obtained (all M plus L ratings).

Thirdly, the receiving equipment of the base station, according to the first embodiment, containing J spatially separated reception branches, each of which contains an antenna, an analog receiver, H data receivers and a search receiver, a diversity adder, a decoder, and a control unit, while the antenna input in each branch of the signal reception is the input of the device, its output is connected to the input of the analog receiver, the output of which is connected to the first input of each data receiver and the input of the search receiver in this reception branch, the output of each data receiver with each branch of the receiver is connected to the corresponding input of the diversity adder, the second input of each data receiver is connected to its corresponding first outputs of the control unit, which are control for data receivers, the output of each search receiver from each branch of the receiver is connected to its corresponding first input of the control unit and is information, the output of the diversity adder is connected to a decoder, the output of which is connected to the second input of the control unit and is an information input, the second and third the outputs of the control unit are the outputs of the receiving equipment of the base station to the system controller, and the third output is information, the fourth output is the control, the third and fourth inputs of the control unit are respectively the information and control inputs of the receiving equipment of the base station, an averaging unit and a frequency analysis unit are additionally introduced,
- in this case, the additional output of each data receiver from each branch of the connection is connected to the corresponding first input of the frequency analysis unit, the second, third and fourth inputs of which are connected respectively to the fourth, fifth and sixth outputs of the control unit, the output of the frequency analysis unit - with the fifth input of the block management
the output of the diversity adder is connected to the first input of the averaging unit,
- the second input of the averaging unit is connected to the seventh output of the control unit, and the output of the averaging unit is connected to the sixth input of the control unit and is the output of a smoothed signal level estimate.

Fourth, the receiving equipment of the base station, according to the second embodiment, containing Q sectors of signal reception, each of which contains J spatially separated reception branches, an adder diversity and a decoder, and a control unit, each reception branch contains an antenna, an analog receiver, H receivers data and the search receiver, the antenna input in each branch of the reception is the input of the device, its output is connected to the input of the analog receiver, the output of which is connected to the first input of each data receiver and the input of the search receiver in this branch reception, the output of each data receiver from each branch of the receiver is connected to the corresponding input of the diversity adder, the second input of each data receiver is connected to its corresponding first outputs of the control unit, which are control for data receivers, the output of each search receiver from each branch of the connection is connected to the corresponding it is the first input of the control unit and is informational for the control unit, the output of the diversity adder is connected to a decoder, the output of which is connected to the second input of the unit and the control is an information input, the second and third outputs of the control unit are the outputs of the receiving equipment of the base station to the system controller, and the third output is information, the fourth output is the control, the third and fourth inputs of the control unit are respectively the information and control inputs of the receiving equipment of the base station , in addition, an adder, an averaging unit and a frequency analysis unit are introduced into each signal receiving sector,
- while the additional output of each data receiver from each branch of the reception is connected to the corresponding first inputs of the frequency analysis unit and the input of the adder and is an information output,
- the output of the adder is connected to the first input of the averaging unit, the output of which is connected to the fifth input of the control unit and is the output of a smoothed estimate of the signal level,
- the second input of the averaging unit is connected to the fourth control output of the control unit,
- the second, third and fourth inputs of the frequency analysis unit are connected respectively to the fifth, sixth and seventh control outputs of the control unit.

 A comparative analysis of the first proposed solutions - the method of switching the base station in a cellular radio communication systems with code division multiplexing, with a prototype shows that the claimed invention is characterized by the presence of new significant features claimed in the characterizing part of the claims. Therefore, the claimed method meets the criterion of "novelty."

 A comparative analysis of the method of switching the base station in cellular radio systems with code division multiplexing with other technical solutions known in the art [1, 2], did not reveal the signs stated in the characterizing part of the claims.

 The introduction of a set of distinctive features allows, in contrast to the well-known technical solutions [1, 2 and 3], in the presence of fast fading in the channel, to more accurately set the moments of the beginning and end of the relay transmission. This allows optimal adjustment of the duration of the soft handoff process, depending on the specific situation and the parameters of the mobile and base stations, which positively affects the quality of communication and system capacity.

 Therefore, the inventive method of switching the base station in cellular radio systems with code division multiplexing meets the criteria of the invention of "novelty", "technical solution", "significant differences" and meets the inventive step.

 A comparative analysis of the second claimed technical solution - a method for estimating the frequency of signal fading in the propagation medium in a radio communication system with a closed loop power control of a mobile station, with a prototype shows that the claimed invention is distinguished by the presence of new significant features claimed in the characterizing part of the claims. Therefore, the claimed method meets the criterion of "novelty."

 A comparative analysis of the method for estimating the frequency of signal fading in the propagation medium in radio systems with a closed loop for adjusting the power of a mobile station with other technical solutions known in the art [1, 2 and 4] did not reveal the features stated in the distinguishing part of the formula.

 The introduction of a set of distinctive features in the claimed technical solution allows, in contrast to the known technical solutions [1, 2, 3 and 4], to have information about the main fading frequency to accurately determine the start and end moments of switching the base station in cellular radio communication systems with code division multiplexing.

 Therefore, the inventive method for estimating the frequency of fading of a signal in a propagation medium in a closed-loop power control radio communication system of a mobile station meets the criteria of the invention of “novelty”, “technical solution of the problem”, “significant differences” and meets the inventive step.

 A comparative analysis of the third claimed technical solution, the receiving equipment of the base station according to the first embodiment, with the prototype shows that the claimed invention is distinguished by the presence of new significant features claimed in the characterizing part of the claims, namely, an averaging unit and a frequency analysis unit are introduced, and accordingly, new connections to the circuit. As a result of these essential distinguishing features introduced into the claims, each base station has the technical means to form an assessment of the quality of the communication channel with this mobile station. The channel quality estimates in the form of a sequence of values are input to the averaging block, which smooths the data stream. The control unit forms for the averaging unit a set of settings necessary to ensure the required suppression of fast fading and allowable distortion of the useful components of the fading spectrum. Smooth channel quality estimates come from the output of the averaging unit to the control unit, which, depending on the particular implementation, uses them to formulate a decision on relay transmission or sends them to the appropriate controller. The decision-making algorithm for relay transmission may consist, in particular, in comparing the available quality estimates of alternative communication channels with a given mobile station. Then the base station, the quality of communication with which is the best, is the best candidate for the service of this mobile station.

 Therefore, the claimed device meets the criterion of "novelty."

 A comparative analysis of the receiving equipment of the base station according to the first embodiment with other technical solutions known in the art [1 and 2] did not reveal the features stated in the distinguishing part of the formula.

 Therefore, the claimed device meets the criteria of the invention of "novelty", "technical solution of the problem", "significant differences" and meets the inventive step.

 A comparative analysis of the fourth claimed technical solution, the receiving equipment of the base station according to the second embodiment, with the prototype shows that the claimed invention is distinguished by the presence of new significant features claimed in the characterizing part of the claims, namely, an adder, an averaging unit are introduced into each signal receiving sector at the base station and a frequency analysis unit, as well as, accordingly, new connections are introduced into the circuit. As a result of these essential distinguishing features introduced into the claims, the user has the opportunity to use a multi-sector base station or to have several base stations in one place, when necessary. Moreover, each sector of the base station or each base station (provided that several base stations are located in one place) has the technical means to form an assessment of the quality of the communication channel with this mobile station. Evaluation of the quality of the communication channel can be expressed in terms of signal-to-noise ratio, the number of errors in the received information, or in other ways. The channel quality estimates in the form of a sequence of values are input to the averaging block in each receiving sector, which smooths the data stream. The control unit generates for the averaging block in all sectors of the reception a set of settings necessary to ensure the required suppression of fast fading and allowable distortion of the useful components of the fading spectrum. Depending on the specific implementation of the averaging unit, its adjustment may consist in changing the integration time, changing the filter coefficients, or adjusting its sampling frequency, etc. Smooth channel quality estimates come from the output of the averaging block from each receiving sector to the control unit, which, depending on the particular implementation, uses them to formulate a decision on hand-off transmission or sends them to the corresponding controller. The handoff decision algorithm may consist, in particular, in comparing the available quality estimates of alternative communication channels between sectors of one base station or base stations located in the same place with this mobile station. Then the receiving sector in a multi-sector base station (from Q sectors) or a base station (from Q located in one place), the quality of communication with which is the best, is the best candidate for servicing this mobile station. Thus, the second embodiment of the receiving equipment of the base station significantly expands the capabilities of the user compared to the first embodiment, in the case when it is necessary.

 Therefore, the claimed device meets the criterion of "novelty."

 A comparative analysis of the receiving equipment of the base station according to the second embodiment with other technical solutions known in the art [1 and 2], did not reveal the signs stated in the distinguishing part of the formula.

 Therefore, the claimed device meets the criteria of the invention of "novelty", "technical solution of the problem", "significant differences" and meets the inventive step.

 The method of switching the base station in cellular radio communication systems with code division multiplexing, the method of estimating the frequency of fading of a signal in the propagation medium in radio communication systems with a closed loop power control of the mobile station and the receiving equipment of the base station (options) were created in a single inventive concept and allowed to solve the problem - this is an increase in the quality and reliability of communication, system capacity and optimality of the distribution of system resources by reducing the effect of fast fading in the channel on making a decision on the handover.

 FIG. 1 explains the principle of soft transmission, where BS1 and BS2 are the base stations of the first and second cells, respectively, BS1.1 and BS1.2 are the sectors of base station 1, respectively; BS2.1 - sector of base station 2; a) the trajectory of the mobile station; b), c) the diagrams of average quality of communication with sectors BS1.1, BS1.2 and BS 2.1 are inappropriate; tl is the time during which the mobile station serves BS1.1, t2 is the time during which the mobile station serves BS1.2, t3 is the time during which the mobile station serves BS2.1. FIG. 2 illustrates the unreliability of decision making using a comparison of the level of pilot signals in the prototype due to fading in the channel. FIG. 3 illustrates a qualitative example of the spectral composition and the type of corresponding signals in the time domain, where a is the spectrum of fast fading (multipath interference); b is the fundamental frequency of fast fading; c - spectrum of slow fading (terrain, shading by large objects); d - slow level changes from the antenna pattern; e - slow level changes due to radial attenuation.

 In FIG. 4 shows a block diagram of the receiving equipment of the base station (prototype). FIG. 5 illustrates a method for switching a base station in a code division multiplex cellular radio communication system (claimed invention) when moving a mobile station from one cell to another. In FIG. 6 presents a block diagram of the receiving equipment of the base station according to the first embodiment (the claimed invention); in FIG. 7 presents a block diagram of the receiving equipment of the base station according to the second embodiment (the claimed invention). In FIG. 8 is a block diagram of a frequency analysis unit, shown as an example of embodiment for receiving equipment of a base station according to the first and second embodiments. In FIG. 9 is a block diagram of an analyzer included in a block diagram of a frequency analysis unit 10, shown as an example of execution.

 The receiving equipment of the base station (prototype) in accordance with FIG. 4 contains J spatially separated receive branches, each receive branch contains an antenna 1-1-1-J, an analog receiver 2-1 - 2-J, H data receivers 3-1 - 3-N - 4-1 - 4-N and a search receiver 5-1 to 5-J, an adder 6 and a decoder 7, and a control unit 8, while the input of the antenna 1-1 - 1-J in each branch of the signal reception is the input of the device, its output is connected to the input of the analog receiver 2-1 - 2-J in its receiving branch, the output of which is connected to the first input of each data receiver 3-1 - 3-J and 4-1 - 4-J and the input of the search receiver 5-1 - 5-J in this branch reception, exit of each reception the data receiver 3-1 - 3-J and 4-1 - 4-J from each receiving branch is connected to the corresponding input of the diversity adder 6, the second input of each data receiver 3-1 - 3-J and 4-1 - 4-J connected to the corresponding first outputs of the control unit 8, which are control for data receivers, the output of each search receiver 5-1 - 5-J from each branch of the reception is connected to the corresponding first input of the control unit 8 and is informational, the output of the diversity adder 6 is connected with decoder 7, the output of which is connected to the second input of the control unit 8 and is an information input, the second and third outputs of the control unit 8 are the outputs of the receiving equipment of the base station to the system controller, and the third output is information, the fourth output is the control, the third and fourth inputs of the control unit 8 are respectively the information and control inputs of the receiving equipment of the base station.

 The receiving equipment of the base station according to the first embodiment (the claimed invention) in accordance with FIG. 6 contains J spatially separated reception branches, each receiving branch contains an antenna 1-1 - 1-J, an analog receiver 2-1 - 2-J, H data receivers 3-1 - 3-N - 4-1 - 4-N and a search receiver 5-1 to 5-J, an adder 6 and a decoder 7, and a control unit 8, while the input of the antenna 1-1 - 1-J in each branch of the signal reception is the first input of the device, its output is connected to the analog input receiver 2- 1 - 2-J, the output of which is connected to the first input of each data receiver 3-1 - 3-J and the input of the search receiver 5-1 - 5-J in the corresponding branch of the receiver, the output of each receiver is data 3-1 - 3-J - 4-1 - 4-N from each receiving branch is connected to the corresponding input of diversity adder 6, the second input of each data receiver 3-1 - 3-J - 4-1-4-N is connected with the corresponding first outputs of the control unit 8, which are control for data receivers, the output of each search receiver 5-1 to 5-J from each branch of the reception is connected to the corresponding first input of the control unit 8 and is informational, the output of the diversity adder 6 is connected to a decoder 7, the output of which is connected to the second input of the control unit 8 and etsya data input, second and third outputs 8 of the control unit are the outputs of the receiving apparatus of the base station to the system controller, and the third output is the information, a fourth output - control, third and fourth inputs of the control unit 8 are respectively an information and control inputs receiving the base station apparatus. In addition, an averaging unit 9 and a frequency analysis unit 10 are additionally introduced into the receiving equipment of the base station in each signal receiving sector, with the additional output of each data receiver 3-1 - 3-H - 4-1 - 4-N from each receiving branch connected to the corresponding first input of the frequency analysis unit 10, the second, third and fourth inputs of which are connected respectively to the fourth, fifth and sixth outputs of the control unit 8, the output of the frequency analysis unit 10 is connected to the fifth input of the control unit 8, the output of diversity adder 6 is connected to first at entry averaging unit 9 in each sector receiving a signal, a second input of the averaging unit 9 is connected to the fifth output of the control unit 8, and the output of the averaging unit 9 - a sixth input of the control unit 8 and is the output signal level of the smoothed evaluation.

 The receiving equipment of the base station according to the second embodiment (the claimed invention) in accordance with FIG. 7 contains Q sectors of signal reception, diversity adder 6, decoder 7, and control unit 8, each sector of signal reception contains J spatially separated reception branches, each of which contains an antenna 1-1 - 1-J, an analog receiver 2-1 - 2-J, H data receivers 3-1 - 3-H and the search receiver 5-1 - 5-J, while the input of the antenna 1-1 - 1-J in each branch of the reception is the input of the device, its output is connected to the analog input receiver 2-1 - 2-J in the corresponding branch of the reception, the output of which is connected to the first input of each data receiver 3-1 - 3-J and the input of the receiver search 5-1 - 5-J in this receiving branch, the output of each data receiver 3-1 - 3-J - 4-1 - 4-N from each receiving branch is connected to its corresponding input of diversity adder 6, the second input of each data receiver 3-1 - 3-J - 4-1 - 4-N is connected to the corresponding first outputs of the control unit 8, which are control for data receivers, the output of each search receiver 5-1 - 5-J from each branch of the reception is connected to the corresponding him the first input of the control unit 8 and is informational, the output of the adder diversity 6 is connected to the decoder 7, the output to which is connected to the second input of the control unit 8 and is an information input, the second and third outputs of the control unit 8 are the outputs of the receiving equipment of the base station to the system controller, and the second output is information, the third output is the control, the third and fourth inputs of the control unit 8 are respectively information and control inputs of the receiving equipment of the base station. In addition, an averaging unit 9, a frequency analysis unit 10 and an adder 11 are additionally introduced into the receiving equipment of the base station in each signal receiving sector, with the additional output of each data receiver 3-1 - 3-H and 4-1 - 4-N each receiving branch is connected to the corresponding first inputs of the frequency analysis unit 10 and the input of the adder 11 and is an information output, the output of the adder 11 is connected to the first input of the averaging unit 9, the output of which is connected to the fifth input of the control unit 8 and is the output of a smoothed signal level estimate la, the second input of the averaging unit 9 is connected to the fourth control output of the control unit 8, the second, third and fourth inputs of the frequency analysis unit 10 are connected respectively to the fifth, sixth and seventh control outputs of the control unit 8.

 Frequency analysis unit 10 may be implemented in various ways, for example, in accordance with FIG. 8 contains series-connected multiplexer 12, multiplier 13 and analyzer 14, while the first inputs of multiplexer 12 are information inputs of this unit, the second input of multiplexer 12 is control (from control unit 8), the output of the multiplexer is connected to the first input of multiplier 13, the second input of which It is also control (from the control unit 8), the output of the multiplier 13 is connected to the first input of the analyzer 14, the second input of which is also control (from the control unit 8), the output of the analyzer is the progress of this block to the control unit 8 and is an information output about the speed of fading in the channel.

 In the block diagram of the frequency analysis unit 10, for example, an adder may be introduced instead of the multiplexer.

 The block diagram of the analyzer 14 for the frequency analysis unit 10 can be made in various ways, for example, in accordance with FIG. 8 comprises a weight function former 15, a multiplier 16 connected in series, a buffer 17, a fast Fourier transform element 18, a comparison element 19.

 The averaging unit 9 can also be implemented in various ways, for example, it can be an integrator, a digital filter, or some other device for smoothing the data stream.

 To implement the method of switching the base station in a code division multiplex cellular radio communication system, N base stations of the cellular radio communication system are used so that the mobile station can communicate with at least one base station at any point in space. N base stations are combined into logical groups so that the active group includes all the base stations through which the mobile station performs duplex communication, and the neighboring group includes all the base stations directly adjacent to the base stations of the active group.

 The method of switching the base station in cellular radio systems with code division multiplexing is implemented as follows (in accordance with Fig. 5).

 For example, in a cellular radio communication system, 1 mobile station is used and it is assumed that the coverage area of one base station is a regular hexagon, then six base stations are adjacent to any base station.

 The mobile station, being in the first cell, communicates with the first base station, which, therefore, is in the active group, and six base stations directly adjacent to the first base station constitute a neighboring group. On command from the system controller, a signal is searched for from the mobile station at each of the six base stations of the neighboring group and its level is estimated. In this case, for example, the second and third base stations of a neighboring group are distinguished, in which the signal level estimates exceed a predetermined threshold value. Then, at the first, second and third base stations, the relative level of the received signal is measured with an interval of not more than the interval between the power control commands. Using information on the frequency of fading in the channel, smooth out the obtained sequence of samples of the relative level at the first, second and third base stations. If at the second base station the smoothed level exceeds a predetermined threshold value, then it is transferred to the active set and the receiver and transmitter are turned on for receiving and transmitting a signal. At the mobile station, all signals of the base stations of the active group are received. Consequently, the composition of the neighboring group has also changed; all base stations directly adjacent to the second base station are additionally included in it. Thus, the neighboring group together included base stations bordering the first base station and base stations bordering the second base station. And the first and second base stations, which support duplex communication with the mobile station, are in the active group.

 With further movement of the mobile station, the smoothed level of the received signal at the first base station decreases below a predetermined threshold value, this base station is removed from the active group and, accordingly, signal reception and transmission stops.

 Now the active group includes only the second base station, and the neighboring group includes base stations adjacent to the second base station.

 A method for switching a base station in code-division-based cellular radio communication systems and a method for estimating a signal fading frequency in a propagation medium in a closed-loop power control radio communication system of a mobile station are implemented on the receiving equipment of one base station (according to the first embodiment) in accordance with FIG. 6.

 The input signal from the mobile station enters the inputs of spatially separated antennas in each branch of the reception 1-1 - 1-J, perform analog-to-digital conversion in analog receivers 2-1 - 2-J. The output signal from analog receivers 2-1 - 2-J goes to the corresponding data receivers 3-1 - 3-N - 4-1 -4-N.

 Search receivers 5-1 to 5-J detect the individual beams of the signal by the delay and information about the detected beam is transmitted to the control unit 8.

 In accordance with the control signal from the control unit 8, data receivers 3-1 -3-J - 4-1 - 4-J demodulate the input signal. The information output of the data receivers 3-1 - 3-J and 4-1 - 4-J in the form of a sequence of modulation symbols is fed to the corresponding input of the diversity adder 6.

 An additional output from each data receiver 3-1 - 3-J and 4-1 - 4-J, which is an information output about the relative signal level, is fed to the corresponding input of the frequency analysis unit 10.

 In diversity adder 6, all symbols are time aligned, multiplied by weights and summed. The result is a sequence of modulation symbols, which is transmitted simultaneously to the decoder 7 and the averaging unit 9. In decoder 7, decode and transmit to the corresponding input of the control unit 8.

 In the averaging unit 9, the obtained modulation symbols obtained in the diversity adder 6 are used to calculate the relative signal level (signal / interference). The resulting sequence of values of the relative level is subjected to smoothing, for example, using a low-pass filter or some other device for smoothing. To configure the averaging unit 9 use information about the main frequency of fading. The output signal from the averaging unit 9 enters the corresponding sixth input of the control unit 8.

 The input signal for the frequency analysis unit 10 (Fig. 8) can be formed by multiplexing or summing additional output signals from data receivers 3-1 - 3-J and 4-1 - 4-J. In this implementation, a multiplexer 12 is used for this, controlled by the signal from the control unit 8. The multiplexer control algorithm may, for example, consist in switching samples of one of the multiplexer receivers to its output until the receiver loses a demodulated beam or until the signal has a level sufficient for analysis. In the event of a loss of a ray or a drop in its level, another data receiver is selected, one for which the minimum time has passed as compared to other receivers from the moment the beam demodulation begins.

 The output signal from the multiplexer 12 (Fig. 8) is supplied to the multiplier 13, where it is multiplied by a sequence of coefficients transmitted from the control unit 8.

 The resulting sequence is subjected to frequency analysis, for example, spectral analysis using the Fourier transform. The spectral component with the highest frequency is determined with a level exceeding a predetermined threshold value set by the control unit 8. The frequency of the found component is used as information about the main fading frequency.

 In the control unit 8, the communication quality is evaluated and power control commands are generated, and if the communication quality assessment at the base station exceeds a predetermined threshold value, a power reduction command is generated; if the communication quality assessment at the base station is less than a predetermined threshold value, an increase command is generated power. The generated commands are transmitted in a direct channel and simultaneously reported to the system controller. A base station that is not part of an active group does not transmit a direct channel signal and does not generate power control commands.

 The output signal from the averaging unit 9, which is a smoothed estimate of the signal level, is transmitted through the control unit 8 to the system controller.

 In accordance with the received information, the system controller generates a sequence of coefficients using power control commands from all base stations of the active group. The coefficients are formed in such a way that, if all commands increase power, then form a coefficient equal to I / A, if at least one team requires a decrease in power, then form a coefficient equal to B, where A is a given step of increasing power (for example + ldB) , V - a given step of reducing power (for example, -ldB). The obtained coefficients are transmitted to all base stations of the active group and base stations of the neighboring group, which monitor the signal level of the mobile station.

 In the system controller, the channel fade rate can be calculated. To do this, all the base stations of the active group and all the base stations of the neighboring group that monitor the signal level of the mobile station transmit to the system controller the results of the fade rate estimate obtained in the frequency analysis unit 10. The system controller calculates a generalized frequency estimate, for example, by averaging the estimates received from base stations. The obtained generalized estimate is transmitted to all base stations of the active group and all base stations of the neighboring group, which monitor the signal level of the mobile station.

 The system controller compares the smoothed level estimates received from base stations (from averaging units 9) with each other or with switching thresholds and, based on the results of the comparison, decides on the composition of the active group.

 The sequence of coefficients received from the system controller is fed to the base station to the second input of the frequency analysis unit 10 (to the multiplier 13 in the frequency analysis unit). Moreover, since the exact time of the execution of the power control command by the mobile station is known in the synchronous communication system, then at the base station (in the control unit 8), the sequence of coefficients is aligned in time with the execution of the power control commands.

 To control the averaging unit 9, generalized frequency estimates from the system controller are used. If the system controller is not used to calculate the generalized estimate, then to control the averaging unit 9 use the output of the frequency analysis unit 10, converted in the control device 8.

 A method for switching a base station in a code division multiple-band cellular radio communication system and a method for estimating a signal fading frequency in a propagation medium in a closed-loop power control radio communication system of a mobile station are implemented on the receiving equipment of the base station (according to the second embodiment) in accordance with FIG. 7. The receiving equipment of the base station according to the second embodiment is used subject to a multi-sector base station. In this case, to improve the quality of reception, the outputs of all data receivers of all the reception branches of all sectors receiving the signal of the mobile station, it is advisable to connect to one multi-input diversity adder 6 (i.e. use one diversity adder 6, one decoder and one control unit for Q signal receiving sectors). Therefore, the averaging units 9 in each sector of the signal reception are connected not to the output of the diversity adder, but through the adder to the additional outputs of the data receivers of the corresponding sector. This is due to the fact that with this inclusion of the diversity adder 6 from its output signal, it is not possible to obtain information about the position of the mobile station relative to the signal receiving sectors, since you cannot compare the levels of signals received in the respective sectors of the reception.

 The methods are implemented as follows.

 The input signal from the mobile station is fed to the inputs of spatially separated antennas in each receiving branch 1-1 to 1-J of each signal receiving sector or each base station (for example, Q signal receiving sectors of one multi-sector base station or Q base stations located in one location), carry out analog-to-digital conversion in analog receivers 2-1 - 1-1. The output signal from analog receivers 2-1 - 2-J in each receiving branch, respectively, is fed to data receivers 3-1 - 3-H - 4-1 - 4-N.

 The search receiver 5-1 - 5-J performs the detection of individual signal beams by the delay; it transmits information about the detected beam to the control unit 8.

 In accordance with the control signal from the control unit, data receivers 3-1 to 3-J and 4-1 to 4-J demodulate the input signal. The information output of the data receivers 3-1 - 3-J and 4-1 - 4-J in the form of a sequence of modulation symbols is fed to the corresponding input of the diversity adder 6.

 An additional output from each data receiver 3-1 - 3-J and 4-1 - 4-J, which is an information output about the relative signal level, is simultaneously fed to the corresponding input of the frequency analysis unit 10 and adder 11.

 In diversity adder 6, all symbols are time aligned, multiplied by weights and summed. The result is a sequence of modulation symbols, which is transmitted to the decoder 7. In the decoder 7 decode and transmit to the corresponding input of the control unit 8.

 In the averaging unit 9, the output signal of the adder 11 is subjected to smoothing, for example using a low-pass filter or some other smoothing device. To configure the averaging unit 9 use information about the main frequency of fading. The output signal from the averaging unit 9 enters the corresponding sixth input of the control unit 8.

 The input signal for the frequency analysis unit 10 (Fig. 8) can be formed by multiplexing or summing additional output signals from data receivers 3-1 - 3-J and 4-1 - 4-J. In this implementation, a multiplexer 12 is used for this, controlled by a signal from the control unit 8. The multiplexer control algorithm may, for example, consist in switching samples of one of the data receivers to its output. In this case, the signal from the selected receiver is transmitted to the output of the multiplexer until the receiver loses a demodulated beam or until the signal has a level sufficient for analysis. In the event of a loss of a ray or a drop in its level, another data receiver is selected, one for which the minimum time has passed as compared to other receivers from the moment the beam demodulation begins.

 Instead of multiplexer 12, an adder may be used.

 The output signal from the multiplexer 12 (Fig. 8) is supplied to the multiplier 13, where it is multiplied by a sequence of coefficients transmitted from the control unit 8.

 The resulting sequence is subjected to frequency analysis, for example, spectral analysis using the Fourier transform. The spectral component with the highest frequency is determined with a level exceeding a predetermined threshold value set by the control unit 8. The frequency of the found component is used as information about the main fading frequency.

 In the control unit 8, the communication quality is evaluated and power control commands are generated, and if the communication quality assessment at the base station exceeds a predetermined threshold value, a power reduction command is generated; if the communication quality assessment at the base station is less than a predetermined threshold value, an increase command is generated power. The generated commands are transmitted in a direct channel and simultaneously reported to the system controller. A base station (sector) that is not part of the active group does not transmit a direct channel signal and does not generate power control commands.

 The output signal from the averaging unit 9, which is a smoothed estimate of the signal level, is transmitted through the control unit 8 to the system controller.

 In accordance with the received information, the system controller generates a sequence of coefficients using power control commands from all base stations of the active group. The coefficients are formed in such a way that, if all commands increase power, then form a coefficient equal to 1 / A, if at least one team requires a decrease in power, then form a coefficient equal to B, where A is the specified step of increasing power (for example + ldB) , V - a given step of reducing power (for example, -ldB). The obtained coefficients are transmitted to all base stations of the active group and base stations of the neighboring group, which monitor the signal level of the mobile station.

 In the system controller, the channel fade rate can be calculated. To do this, all the base stations of the active group and all the base stations of the neighboring group that monitor the signal level of the mobile station transmit to the system controller the results of the estimation of the fading frequency obtained in the frequency analysis unit 10.

 The system controller calculates a generalized frequency estimate, for example, by averaging the estimates received from the base stations. The obtained generalized estimate is transmitted to all base stations of the active group and all base stations of the neighboring group, which monitor the signal level of the mobile station. The system controller compares the smoothed level estimates received from base stations (from averaging units 9) with each other or with switching thresholds and, based on the results of the comparison, decides on the composition of the active group.

 At the base station, the sequence of coefficients received from the system controller is fed to the second input of the frequency analysis unit 10 (to the multiplier 13). Moreover, since the exact time of the execution of the power control command by the mobile station is known in the synchronous communication system, then at the base station (in the control unit 8), the sequence of coefficients is aligned in time with the execution of the power control commands.

 To control the averaging unit 9, generalized frequency estimates from the system controller are used. If the system controller is not used to calculate the generalized estimate, then to control the averaging unit 9 use the output of the frequency analysis unit 10, converted in the control unit 8.

 The outputs of Q averaging blocks (from all sectors of the signal reception) are connected to the control unit 8, so it can autonomously (without the participation of the system controller) control the switching procedure with respect to the data of Q signal reception sectors.

 Computer simulation of the method of switching the base station in cellular radio systems with code division multiplexing, a method for estimating the frequency of fading of a signal in a propagation medium in radio communication systems with a closed loop for adjusting the power of the mobile station and the receiving equipment of the base station (options), showed that the claimed inventions possess a number of significant advantages compared with known technical solutions in the art. For example, the accuracy of setting the start and end moments of the relay transmission is improved compared to the prototype more than 3 times, the effect of ping-pong has been eliminated.

 The method of switching the base station in cellular radio systems with code division multiplexing in the presence of fast fading in the communication channel allows for more accurate setting of the start and end moments of the relay transmission and their adjustment over a wide range, and also eliminates erroneous switching. This allows you to optimally adjust the duration of the soft relay process, depending on the specific situation and features of the system architecture and signal processing methods, which positively affects the quality of communication and system capacity.

 A method for estimating the frequency of fading of a signal in a propagation medium in radio systems with a closed loop for adjusting the power of a mobile station allows one to have information about the main frequency of fading to accurately determine the moments of the beginning and end of switching of a base station in cellular radio communication systems with code division multiplexing. The method can also be used in other applications, for example, within the framework of the system in question, information on the fading frequency can be used to improve the algorithm for adjusting the power of a mobile station.

 The receiving equipment of the base station according to the first embodiment, as a result of introducing an averaging block and a frequency analysis block and, accordingly, new links into the block diagram, allows obtaining smoothed estimates of the quality of the communication channel, that is, reducing the influence of fast fading in the channel on the reliability of the decision about hand-off . The control unit, on the basis of information about the main fading frequency (speed of the mobile station), forms for the averaging block a set of settings necessary to ensure the required suppression of fast fading and the allowable distortion of the useful components of the fading spectrum. Smooth channel quality estimates come from the output of the averaging unit to the control unit, which, depending on the particular implementation, uses them to formulate a decision on relay transmission or sends them to the appropriate controller. The decision-making algorithm for relay transmission may consist, in particular, in comparing the available quality estimates of alternative communication channels with a given mobile station. Then the base station, the quality of communication with which is the best, is the best candidate for the service of this mobile station.

 The receiving equipment of the base station according to the second embodiment with the new blocks and connections introduced into it allows you to get similar advantages, however, its feature is that it makes it possible to implement the claimed methods using a different structure of the base station (cell). Such a structure can be used, for example, in multi-sector cell division. When moving a mobile station between sectors of a base station, a signal from it can be received by data receivers simultaneously in several sectors. The signals received in different sectors can then be combined on a single diversity adder, which under certain conditions will give a significant gain in reception quality. However, at the same time, information about the position of the mobile station relative to neighboring sectors cannot be obtained at the output of the diversity adder. Therefore, in the second version of the receiving equipment, another inclusion of an averaging unit is proposed, which forms smoothed estimates of the quality of the communication channel in this sector.

 In the aggregate, the claimed group of inventions allows to improve the quality and reliability of communication, increase the capacity of the system and optimally allocate system resources due to more accurate installation of the moments of the beginning and end of the relay transmission in the presence of fast fading in the communication channel.

Sources of information
1. The compatibility standard of the mobile and base stations for dual-mode cellular broadband systems with spreading. TIA / EIA / IS-95-A, may 1995. Telecommunications Industry Association.

2. US patent N 5101501, MKI ⁵ H 04 Q 7/00, H 04 M 11/00.

3. US patent N 5345467, MKI ⁵ H 04 L 27/30 "Method and device for handoff in the CDMA system."

 4. Ed. K.A. Samoilo. Radio circuits and signals. M .: Radio and communication. -1982, p. 267 - 268.

 5. S. L. Marple ml. Ed. I.S. Ryzhak. Digital spectral analysis and its application. M .: World. 1990.

Claims (4)

 1. The method of switching the base station in cellular radio systems with code division multiplexing, which use N base stations of the cellular radio communication system so that the mobile station at any point in space can communicate with at least one base station, namely, that combine N base stations into logical groups so that the active group includes all base stations through which the mobile station performs duplex communication, and the neighboring group includes all base stations and, directly adjacent to the base stations of the active group, evaluate the parameters of the communication channels with the mobile station through each of the M base stations of the active group and each of the K base stations of the neighboring group, compare with a predetermined threshold, moreover, if the channel parameters estimate is any of K base stations of a neighboring group exceeds a predetermined threshold value, then such a base station is transferred to the active group and channels for receiving and transmitting a signal for the mobile station are formed on it if the channel if any of the M base stations of the active group is below a predetermined threshold value, then when M is greater than 1, such a base station is excluded from the active set, while the channels of signal reception and transmission are deleted on it, characterized in that they search for the signal of the mobile station on each from K base stations of a neighboring group and evaluate its level, select L channels from K channels of a neighboring group, in which signal level estimates exceed a predetermined threshold value, estimate the frequency of signal fading from a mobile station in a distribution medium wandering, calculate a smoothed estimate of the signal level from the mobile station in each of the L channels of the neighboring group and in each of the M channels of the active group by adaptively smoothing the sequence of estimates of the level of the received signal, using information on the basic frequency of signal fading for adaptation, thus obtaining M plus L smoothed estimates, the obtained smoothed level estimates are compared with each other or with switching thresholds and, based on the results of the comparison, decide on the composition of the active group.  2. A method for estimating the frequency of fading of a signal in a propagation medium in radio systems with a closed loop for adjusting the power of a mobile station, in which the quality of communication at each of the M base stations of the active group is evaluated with an interval equal to the interval between power control commands and commands are transmitted to the mobile station power control, moreover, if the assessment of the quality of communication at the base station exceeds a predetermined threshold value, then a command to reduce power is generated if the assessment of the quality of communication at the base station and less than a predetermined threshold value, form a command to increase power, allocate power control commands from each of the M received signals from the mobile station and adjust the power in such a way that if all the received commands require an increase in power, then increase the power by a factor of A, if, although if one team requires a decrease in power, it is reduced by a factor of time, where A is the specified step of increasing power, B is the specified step of decreasing power, which consists in measuring the relative level of the received signal for each one of K base stations of a neighboring group, characterized in that the relative level of the received signal is measured at each L of K base stations of a neighboring group, in which the signal level estimates exceed a predetermined threshold value, with an interval equal to the interval between power adjustment commands, form M plus L sequences of samples, are stored at each of the M base stations of the active group, power control commands transmitted to the mobile station are formed, a sequence of coefficients is formed, while using remembered commands in such a way that if all M teams require an increase in power, then form a coefficient equal to I / A, if at least one team requires a decrease in power, then form a coefficient equal to B, correct the sequence of samples of the relative level of the received signal on each of M base stations of the active group and at each of the L base stations of the neighboring group by multiplying the elements of the original sequences by the corresponding elements of the obtained sequence of coefficients, form estimates about the new frequency of signal fading by frequency analysis of the obtained corrected sequences at each of the M base stations of the active group and at each of the L base stations of the neighboring group, thus forming M plus L ratings, calculate the average estimate of the fundamental frequency of signal fading in the propagation medium for this mobile station , using all the estimates obtained - all M plus L ratings.  3. The receiving equipment of the base station, containing J spatially separated reception branches, each of which contains an antenna, an analog receiver, H data receivers and a search receiver, a diversity adder, a decoder and a control unit, while the antenna input in each signal receiving branch is an input device, its output is connected to the input of an analog receiver, the output of which is connected to the first input of each data receiver and the input of the search receiver in this receive branch, the output of each data receiver from each receive branch is connected to the corresponding input of the diversity adder, the second input of each data receiver is connected to the corresponding first outputs of the control unit, which are control for the data receivers, the output of each search receiver from each branch of the reception is connected to the corresponding first input of the control unit and is information, the output of the adder diversity is connected to a decoder, the output of which is connected to the second input of the control unit and is an information input, the second and third outputs of the control unit are are the outputs of the receiving equipment of the base station to the system controller, and the third output is information, the fourth output is the control, the third and fourth inputs of the control unit are respectively the information and control inputs of the receiving equipment of the base station, characterized in that an averaging unit and a frequency analysis unit are introduced, an additional output of each data receiver from each receiving branch is connected to the corresponding first input of the frequency analysis unit, the second, third and fourth inputs of which connected to the fourth, fifth and sixth outputs of the control unit, the output of the frequency analysis unit - with the fifth input of the control unit, the output of the diversity adder is connected to the first input of the averaging unit, the second input of the averaging unit is connected to the seventh output of the control unit, and the output of the averaging unit is with the sixth input of the control unit and is the output of a smoothed signal level estimate.  4. The receiving equipment of the base station, containing Q sectors of signal reception, each of which contains J spatially separated reception branches, a diversity adder and a decoder, and a control unit, each receiving branch contains an antenna, an analog receiver, H data receivers and a search receiver, input the antenna in each branch of the reception is the input of the device, its output is connected to the input of the analog receiver, the output of which is connected to the first input of each data receiver and the input of the search receiver in this branch of the reception, the output of each receiver and the data from each branch of the receiver is connected to the corresponding input of the diversity adder, the second input of each data receiver is connected to its corresponding first outputs of the control unit, which are control for data receivers, the output of each search receiver from each branch of the receiver is connected to its corresponding first input of the block control is informational for the control unit, the output of the diversity adder is connected to a decoder, the output of which is connected to the second input of the control unit and is inform the input, the second and third outputs of the control unit are the outputs of the receiving equipment of the base station to the system controller, and the third output is information, the fourth output is the control, the third and fourth inputs of the control unit are respectively information and control inputs of the receiving equipment of the base station, characterized in that an adder, an averaging unit, and a frequency analysis unit, an additional output of each data receiver from each receiving branch of the input connected to the corresponding first inputs of the frequency analysis unit and the input of the adder and is an information output, the output of the adder is connected to the first input of the averaging unit, the output of which is connected to the fifth input of the control unit and is the output of a smoothed signal level estimate, the second input of the averaging unit is connected to the fourth control the output of the control unit, the second, third and fourth inputs of the frequency analysis unit are connected respectively to the fifth, sixth and seventh control outputs of the control unit.

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