RU2291568C1 - Method for transferring service of client station between base stations of various cell phone networks, one of which has priority relatively to another one, and device for realization of method - Google Patents

Abstract

FIELD: radio engineering, possible use for transferring service of client station between base stations of two various cell networks (inter-system "hand-off"), one of which has priority relatively to another one.

SUBSTANCE: method includes introducing intermediate state of simultaneous connection of client station to priority base station and non-priority base station, set by two thresholds for power of base station signal of priority network and four given time intervals, determining base station signal power comparison intervals of priority network to given two thresholds. Intermediate state of simultaneous connection of client station and base station of priority network and non-priority network allows in case of feeding effecting to increased quality and reliability of communication during transfer of service of client station between base stations of various cell networks by decreased frequency of client service transfer from source base station to adjacent base station of network and vice versa (decreased frequency of ping-pong effect).

EFFECT: increased quality and reliability of communication during transfer of service to client station.

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Description

The invention relates to the field of radio engineering, in particular to a method and device for handing off a subscriber station (AC) between base stations (BS) of two different cellular networks, one of which is priority over the second, and can be used in wireless cellular communication systems.

A prerequisite for the effective operation of modern wireless communication systems is to maintain communication when moving a mobile speaker from the service area of one network to the service area of another network and when choosing the type of service in the area of overlapping service areas of several networks.

Transferring AC service between base stations of two different cellular networks is a procedure for managing the flow of transmitted information in wireless communication systems, which ensures that users of the AC maintain communication when moving between networks and when choosing the type of service in the area of overlapping service areas of several networks. This procedure is called intersystem “hand-off” (handoff), for example, [1] K.Pahlavan, P. Krishnamurthy, A. Hatami, M. Ylianttila, J.P. Makela, R.Pichna, Jari Vallstrom. "Handoff in hybrid mobile data networks" IEEE Personal Communication, vol. 7, issue 2, Apr. 2000.

At present, the procedure for transferring AC service between base stations of two different cellular networks is usually divided into two types: “hard” inter-system transmission and “soft” inter-system transmission of AC service. A “hard” intersystem AS service transfer is based on the principle of “disconnect (AS from the BS of the source network) before connecting (AS from the BS of the new network)”. Thus, with a “hard” intersystem service transfer, the AS is served at only one BS at any time. There is a certain time interval for a “soft” inter-system handover of an AS, during which the AS is simultaneously served by at least two BSs that participate in the AS handover procedure. In this case, the principle of "connect (speakers with the BS of the new network) before disconnecting (speakers with the BS of the source network)" [1] K. Pahlavan, P. Krishnamurthy, A. Hatami, M. Ylianttila, JP Makela, R. Pichna, Jari Vallstrom. "Handoff in hybrid mobile data networks" IEEE Personal Communication, vol. 7, issue 2, Apr. 2000.

A soft intersystem AC handover can be performed between neighboring CDMA systems if these systems operate on the same frequency. If it is impossible to perform a “soft” inter-system handover of an AC, a “hard” inter-system hand-off of an AS is performed. For example, between CDMA systems with different frequencies.

The intersystem handover procedure is determined by the properties of cellular networks. We can distinguish the following main properties of modern cellular networks that determine the procedure for intersystem transfer of service to speakers.

- Different networks support different types of service. When performing the intersystem handover procedure, the speakers take into account the priority of the required service. For example, networks support different data rates. In this case, when performing a handover, priority is given to the data rate. AC handoff priority is higher for networks that support higher data rates. For example, a WLAN network can support a data transfer rate of 2 Mbit / s, and a GPRS (General Packet Radio System) system only from 10 to 100 kbit / s. In this case, the priority from the WLAN to the GPRS system is lower than in the opposite direction. Another example: the priority of the network can be determined by the cost of the services provided.

- AU should provide priority network service as early as possible and maintain priority network service for as long as possible.

- The coverage areas of different networks may overlap. In this case, at any time, it is possible to perform intersystem handover of the AC. In this case, the AC service transfer is performed taking into account the priorities of overlapping networks.

- A cell or a group of adjacent cells of a priority network can cover only part of the coverage area of a non-priority network. Moreover, the priority network may have cells of various sizes.

- Signal strengths of base stations of different networks can vary significantly.

Different networks, as a rule, operate at different frequencies and use various telecommunication technologies (for example, CDMA and OFDM). Therefore, speakers providing operation in several networks with different frequency ranges and different telecommunication technologies should include several receivers with corresponding frequency ranges and supporting the corresponding telecommunication technologies. In this case, the AS can simultaneously receive the BS signals of several networks.

When performing AC handoff between base stations of various cellular networks in the conditions of fading, a ping-pong effect often occurs, which worsens the quality and reliability of communication. When ping-pong, useless (false) handoffs of speakers between base stations of various cellular networks in the forward and reverse directions arise. The ping-pong effect can occur both when the signal strength of the base stations changes when the speakers move, and when the position of the speakers changes with respect to the boundaries of the networks. [2] YE Min-hua, LIU Yu, ZHANG Hui-min THE MOBILE IP HANDOFF BETWEEN HYBRID NETWORKS PIMRC 2002, The 13th IEEE International Symposium on Personal, Indoor and Mobile Communications, September 15-18, 2002, Lisboa, Portuga www. ctr.kcl.ac.uk/Private/ Mischa / PIMRC2002 / papers / cr1002.pdf.

With an increase in the frequency of the ping-pong effect, such undesirable phenomena as speech impairment during the transmission of voice messages, an increase in the load of the network and processors of all levels (AS, BS, and network level) arise.

There are various methods for transferring AC service between base stations of two different cellular networks, for example, the method described in [3] of US patent No. 5,999.816 "Method and apparatus for performing mobile assisted hard handoff between communication systems", Int. Cl ⁶ . H 04 Q 7/00.

The patent proposes a method and apparatus for a hard intersystem AS service transfer when moving this station between two networks. The BS of the first network determines the base stations of the second network adjacent to the served AC. The list of these BSs and their parameters (signal frequency, signal delay, etc.) the original BS of the first network transmits to the served AS, which receives the BS pilot signals listed in the list, and compares the powers of these pilot signals with the pilot threshold. If the threshold is exceeded, then decide that the transfer of service AC is successful. Otherwise, the total signal power in the received AC frequency band is compared with the total power threshold. If the threshold is exceeded, then decide that the neighboring BS of the second network is not included in the list. Otherwise, the AC service transfer is considered failed and the AC is served by the original BS. If the threshold of total power is exceeded, then the AS searches for the neighboring BS of the second network. If a neighboring BS of the second network is detected, then a decision is made that the AC handover is successful.

If the transfer of the AC service did not take place, then information received during the attempt to transfer the service (parameters of the base stations of the new network: frequency, delay and signal strength, etc.) is stored on the AC, and with some delay and taking into account the information received during the previous transmission attempt service, perform the following attempt to transfer the service AC.

One of the possible implementations of the considered method of transferring AC service between base stations of two different cellular networks is a device that is part of the AC and consists of a pilot energy accumulator and a total signal energy accumulator in the reception band, pilot signal and total energy comparison circuits energy with predetermined thresholds, made in software on the processor, and the pilot search block.

In this patent, to perform a service transfer, the AC of the first network determines the base stations of the second network adjacent to the served AC, and the list of these BS transmits to the served AC, which receives the BS pilot signals in the list and compares the powers of these pilot signals with a threshold pilot signal. If the threshold is exceeded, then decide that the transfer of service AC is successful. Under fading conditions, a ping-pong effect occurs, in which false AC service transfers are made between the base stations of the first and second networks in the forward and reverse directions.

Another known method of transferring AC service between base stations of two different cellular networks is described in the article [1] by K. Pahlavan, P. Krishnamurthy, A. Hatami, M. Ylianttila, J.P. Makela, R. Pichna, Jari Vallstrom. "Handoff in hybrid mobile data networks" IEEE Personal Communication, vol. 7, issue 2, Apr. 2000.

At the AS served by the BS of the non-priority network, the detection of the neighboring BS of the priority network is performed. If a neighboring BS of the priority network is detected, the AS disconnects from the BS of the non-priority network and establishes communication with the BS of the priority network.

After establishing a connection between the AU and the BS of the priority network, the signal strength of the BS of the priority network with a predetermined threshold is compared. If the signal power of the BS of the priority network is less than the threshold for a given time interval, then the neighboring BS of the non-priority network is determined at the AS, the connection with the BS of the priority network is disconnected and communication is established from the BS of the non-priority network.

In this method, a “hard” intersystem AS service transfer is performed immediately upon detection of a neighboring BS of a priority network. Under fading conditions, this leads to a ping-pong effect.

The closest technical solution (prototype) to the claimed invention is the method described in article [4] YE Min-hua, LIN Yu, ZHANG Hui-min THE MOBILE IP HANDOFF BETWEEN HYBRID NETWORKS IEEE Personal Indoor and mobile Communication (PIMRC 2002).

Before the transfer of service to the AS between the base stations of two different cellular networks on the AS served by the BS non-priority network, determine the neighboring BS priority network.

1. AC power is compared neighbor BS priority network signal from input P _with a threshold P _Rin network.

2. If the signal power of the neighboring BS of the priority network does not exceed the threshold of entering the network P _I or exceeds for less than T _I , then the signal strength of the neighboring BS of the priority network with the threshold of entering the network P _{I is} compared until signal of the neighboring BSs priority network exceeds a threshold input _Rin network F for a time greater than a predetermined time T _in the interval.

3. If the power of the neighboring BSs priority network signal input exceeds a threshold P _Rin network for a time greater than a predetermined time T _in the interval, the AC to communicate with only the BS priority network.

4. After establishing a connection between the AU and the BS of the priority network on the AS, the signal strength of the BS of the priority network is compared with the exit threshold _Pout .

5. If the signal power of the BS of the priority network is less than the exit threshold of the network P _o for a time longer than the specified time interval T _o , then the speakers only communicate with the BS of the non-priority network.

6. If the power of the signal of the BS of the priority network is greater than the threshold of exit from the network P _o or less for a time shorter than the specified time interval T _o , then the speaker again compares the power of the signal of the BS of the priority network with the threshold of exiting the network P _o until the signal power of the BS of the priority network will be less than the threshold for exiting the network P _o for a time longer than the specified time interval T _o .

The article describing the prototype method does not describe the device that implements this method. However, according to the algorithm described in the description, it is possible to imagine a device that implements the prototype method. One possible implementation based on well-known building blocks is shown in FIG.

The device (figure 1) contains the first 1 and second 2 comparison blocks with a threshold, the first 3 and second 4 logic gates And, the first 5 and second 6 counters, a clock 7, the first 8 and second 9 triggers, while the inputs of the first 1 and the second 2 comparison blocks with a threshold are combined to form the first input of the device, the output of the first comparison block with threshold 1 is connected to the first input of the first logical element And 3, the output of the second comparison block with threshold 2 is connected to the first input of the second logical element And 4, second inputs the first 3 and second 4 are logical And AND elements are combined, forming the second input of the device, the output of the first logical element And 3 is connected to the first input of the first counter 5, the output of the second logic elements And 4 is connected to the first input of the second counter 6, the second inputs of the first 5 and second 6 counters are combined and connected to the output of the clock generator 7, the output of the first counter 2 is connected to the first inputs of the first 8 and second 9 triggers, the output of the second counter 6 is connected to the second inputs of the first 8 and second 9 triggers, the output of the first trigger 8 is the first in the output of the device, the output of the second 9 trigger is connected to the third input of the second logical element And 4 and is the second output of the device.

Implement the prototype method as follows (figure 1).

After determining the AC of the neighboring BS of the priority network, the detection signal of the BS of the priority network and the signal strength of the signal of the BS of the priority network are supplied to the AC transmission device.

The first comparison unit with a threshold 1 compares the signal strength priority BSs neighboring network input threshold of P _Rin network.

If the signal power of the neighboring BS of the priority network exceeds the threshold of entry into the network P _I , the output signal of the first comparison unit 1 through the first logical element And 3 enters the first counter 5 and turns it on. If the power of the neighboring BSs signal priority network exceeds the threshold input of P _Rin network for a time equal to or greater than a predetermined time T _in the interval, then the first counter 5 outputs received signal that sets the first flip-flop 8 in the "zero state", and the second trigger 9 into a "single state". Thus, at the output of the second trigger 9, a signal is established for establishing communication with the BS of the priority network (level of "logical unit"), and at the output of the first trigger 8, the level of "logical zero" is formed. The generated signals from the outputs of the first 8 and second 9 triggers are received respectively at the first and second outputs of the device.

The output signal of the second trigger 9 is supplied to the third input of the second logical element And 4. If the signal power of the BS of the priority network is less than the exit threshold of the network P _o , then the first input of the second logical element And 4 receives the signal from the output of the second comparison unit with threshold 2. When this output of the second logical element And 4 receives a signal at the first input of the second counter 6 and turns it on. If the signal power of the neighboring BS of the priority network is less than the threshold for exiting the network P _o during the time interval T _o , then a signal is output from the output of the second counter 6, setting the first trigger 8 to "single state" and the second trigger 9 to "zero state". Thus, at the output of the first trigger 8, a signal is established for establishing communication with a BS of a non-priority network (level of "logical unit"), and at the output of the second trigger 9, a level of "logical zero" is formed. The generated signals from the outputs of the first 8 and second 9 triggers are received respectively at the first and second outputs of the device.

The threshold of entry into the network P _I must meet conflicting requirements. To reduce the frequency of the “ping-pong” effect, it needs to be increased (the greater the signal power of the neighboring BS of the priority network, the less is the probability of a reverse transition), and to reduce the delay of the transmission of the AC service from the BS of the priority network to the BS, the network entry threshold must be reduced ( the earlier the transition begins, the longer the speaker will work in the priority network). In this case, some compromise solution is chosen. Therefore, the prototype method in the conditions of fading does not allow you to effectively deal with "ping-pong."

The exit threshold of the network P _o should also satisfy conflicting requirements. To reduce the frequency of the ping-pong effect, it is necessary to reduce it: the lower the signal power of the neighboring BS of the priority network, the lower the probability of a reverse transition. Moreover, under fading conditions, the signal of the BS of the priority network may decrease to such a value that it will be lost until the completion of the AC service transfer. [3] Howard G. Ebersman and Ozan K. Tonguz "Handoff Ordering Using Signal Prediction Priority Queuing in Personal Communication Systems" IEEE Trans. Veh. Technol, vol. 48, no. 1, JANUARY 1999. To eat in the conditions of fading, the probability of signal loss increases. In this case, some compromise solution is also chosen. Therefore, the prototype method in the conditions of fading does not allow you to effectively deal with "ping-pong."

The problem to which the claimed invention is directed is to improve the quality and reliability of communication during AS service transfer, which is achieved by decreasing the AS service transmission frequency from the original BS to the neighboring one and vice versa (reducing the frequency of the ping-pong effect).

The inventive method of transferring service to the AS between the base stations of two different cellular networks, one of which is priority over the second, in which the neighboring BS of the priority network is determined on the AS served by the source BS of the non-priority network, that

at the AC, the signal strength of the neighboring BS of the priority network P _{c is} compared with the threshold for supporting simultaneous communication with priority and non-priority networks P _{2 s} ,

if the signal power of the neighboring BS of the priority network P _c does not exceed the threshold for simultaneous communication with the priority and non-priority networks of P _{2 s} or exceeds it for a time T shorter than the specified interval T _2s , then the signal power of the neighboring BS of the priority network of R _s with a threshold is compared P _2s until the signal of the neighboring BS of the priority network P _c exceeds the predetermined threshold P _2c for a time longer than the specified interval T _2s ,

if a neighboring BS signal strength priority network P _c exceeds the threshold simultaneous communication with the priority and non-priority networks R _2c for a time greater than a predetermined interval T _2c for AS communicate with BSs neighboring the priority network and communicate simultaneously with the base stations of priority and non-priority networks ,

after linking AU from the BS priority network to AC with a period T ₁ compared output signal BS priority network F _with a threshold simultaneous communication with the priority and non-priority networks R _2c and the threshold communication only with the priority network P _ave, wherein the threshold P _ave greater than the threshold P _2s

Only if the threshold communications network with priority P _ave is not exceeded, and the threshold simultaneous communication with the priority and non-priority networks R _2c exceeded, then in AU again with a period T ₁ compares the priority network BS power signal P _{with the} thresholds R _2c and R _pr

if the threshold for simultaneous communication with priority and non-priority networks P2 _{s is} not exceeded for a time longer than the specified interval T _{o2 s} , then only the non-priority network is connected to the BSs.

if the communication threshold with the priority network P _{pr is} exceeded for a time longer than the specified interval T _pr , the speakers only communicate with the BS of the priority network and compare the signal strength of the BS of the priority network P _with the threshold T ₂ with the threshold of simultaneous communication with the priority and non-priority networks R _2c, and with regard to the priority threshold only network P _ave.

if the communication threshold only with the priority network P _{pr is} exceeded or less than it during the time T, less than the specified interval T _{o. pr} , then on the AC again with the period T ₂ compare the signal strength of the BS of the priority network P _with the threshold of simultaneous communication with the priority and non-priority networks P _2s and the communication threshold only with the priority network P _pr until the signal power of the neighboring BS of the priority network is less than the threshold P _CR and more than the threshold P _{2 s} for a time T equal to or greater than the specified interval T _out.pr.

if the signal power of the neighboring BS of the priority network P _c is less than the threshold P _pr and more than the threshold P _2s for a time T longer than the specified interval T _output.pr , then the communication with the BS of the neighboring non-priority network is established on the AC and communication is simultaneously with the priority BS non-priority networks and then to AC again with a period T ₁ compared to the signal power P BS priority network _with a threshold simultaneous communication with the priority and non-priority networks R _2c and establishing connection with threshold priority network P _ave.

In this case, the neighboring BS of the priority network is determined at the AS, for example, by searching for the BS signals of the neighboring cells of the priority network in a given time-frequency domain, remembering the signal strengths of the detected signals of the neighboring cells of the BS of the priority network, averaging them, choosing a signal with the maximum average power, making a decision that the selected signal is a signal of a neighboring BS of a priority network, remembering the time-frequency position of a signal of a neighboring BS of a priority network.

The inventive transmission service of the subscriber station, containing the first and second blocks of comparison with a threshold, the first and second logic gates And, the first and second counters, a clock, the first and second triggers, while the inputs of the first and second blocks of comparison with the threshold are combined, forming the first input of the device, the output of the first comparison unit with a threshold is connected to the first input of the first logical element And, the output of the second comparison unit with a threshold is connected to the first input of the second logical element And, second the input inputs of the first and second logical elements AND are combined to form the second input of the device, the output of the clock generator is connected to the first inputs of the first and second counters, the output of the second counter is connected to the first input of the second trigger, the output of which is the second output of the device, and the output of the first trigger is the first output of the device according to the invention further comprises:

the first, second and third logical elements are NOT,

third, fourth and fifth logical elements AND,

third and fourth counters,

first, second and third logical elements OR,

wherein the output of the first logical element AND is connected to the input of the first logical element NOT and the second input of the second counter,

the output of the second logical element AND is connected to the input of the second logical element NOT and the first input of the third logical element AND,

the output of the first logic element is NOT connected to the second input of the third logical element And, the output of which is connected to the second input of the first counter and the first input of the fourth logical element And,

the output of the second logical element is NOT connected to the first inputs of the first and third logical elements OR and the fifth logical element AND,

the first inputs of the third and fourth counters are connected to the output of the clock generator,

the output of the first counter is connected to the first input of the second logical element OR and the second input of the third logical element OR,

the second input of the second logic element OR is connected to the output of the second counter,

the third inputs of the second and third logical elements OR are connected to the output of the third counter,

the output of the fourth counter is connected to the second input of the first OR gate and the fourth input of the third OR gate, the output of which is connected to the second input of the second trigger,

the outputs of the first and second logical elements OR are connected respectively to the first and second inputs of the first trigger,

the output of the first trigger is connected to the second inputs of the fourth and fifth logical elements And,

the output of the fourth logical element And is connected to the second input of the third counter,

the output of the fifth logical element AND is connected to the second input of the fourth counter,

the output of the second trigger is connected to the input of the third logical element NOT and the third input of the fifth logical element AND,

the output of the third logical element is NOT connected to the third input of the fourth logical element I.

The inventive method of transferring AC service between base stations of two different cellular networks, compared with the known technical solutions in the art found during the search, has novelty and allows to obtain a new technical effect, namely to improve the quality and reliability of communication during the transfer of AC service. The technical effect is achieved by reducing the frequency of the transmission service of the AS from the original BS to the neighboring and vice versa (reducing the frequency of the ping-pong effect). The resulting technical effect is achieved by performing the following sequence of actions:

1. AC power is compared neighbor BS P priority network _signal with a threshold to support simultaneous communications with the priority and non-priority networks P _2c. This operation is new compared to the prototype, because compared to the prior art power neighboring BSs priority network signal from input P _to P threshold in _Rin network.

The threshold for supporting simultaneous communication with priority and non-priority networks P _{2s is} less than the threshold for entering the network P _I , since if the threshold P _{2c is} exceeded for a time longer than the specified interval T _2s , the AC simultaneously maintains communication with the basic ones to increase the reliability (reliability) of the handover stations of priority and non-priority networks. In the case of false exceeding of the threshold Р _2с due to the influence of fading, the presence of the AC connection with the base stations of the priority and non-priority networks reduces the time of the reverse transition from simultaneous communication with the base stations of the priority and non-priority networks to communication only with the BS of the non-priority network. In practice, the reverse transition is performed without delay. Thus, the frequency of ping-pong is reduced. Therefore, these operations are not equivalent.

2. If the signal power of the neighboring BS of the priority network P _s does not exceed the threshold for simultaneous communication with the priority and non-priority networks P _2s or exceeds it for a time T shorter than the specified interval T _2s , then the signal strength of the neighboring BS of the priority network P _{s is} compared on the AC threshold P _2s until the signal of the neighboring BS priority network P _c exceeds threshold P _2c for a time longer than the specified interval T _2s . This operation is new compared to the prototype, because compared to the prior art power neighboring BSs priority network signal from the network input threshold P _Rin as long as the signal priority BSs neighboring network exceeds a threshold input P _Rin network for a time equal to or greater than a predetermined time T _in the interval. The specified time interval T _{2s is} greater than the specified time interval T _I , since when the threshold is exceeded P _{2s, the} AC simultaneously communicates with the base stations of the priority and non-priority networks and therefore, to increase the reliability (reliability) of the AC service transmission under fading conditions, the time interval T _2s can be increased . An increase in the T _{2 s} time interval improves the AS handoff procedure and its reliability (ping-pong frequency decreases).

3. If the power of the neighboring BSs priority network signal exceeds the threshold P _with simultaneous communication with the priority and non-priority networks R _2c for a time greater than a predetermined interval T _2c for AS communicate with BSs neighboring the priority network and communicate simultaneously with the base stations and the priority non-priority networks. This operation is new compared to the prototype. AS, to increase the reliability (reliability) of the handover, when the threshold P _{2c is} exceeded for a time longer than the specified interval T _2s , it simultaneously communicates with base stations of priority and non-priority networks. In the case of false exceeding of the threshold Р _2с due to the influence of the fading, the presence of the AS connection with the base stations of the priority and non-priority networks reduces the time of the reverse transition from simultaneous communication with the base stations of the priority and non-priority networks to communication only with the BS of the non-priority network. In practice, the reverse transition is performed without delay. Thus, the frequency of ping-pong is reduced.

Next, we consider a new (relative to the prior art) sequence of operations 4-9, providing the claimed invention with a new technical effect.

4. After establishing communication between the AU and the BS of the priority network on the AS with a period of T ₁ , the signal strength of the BS of the priority network P _{s is} compared with the threshold of simultaneous communication with the priority and non-priority networks P _2s and the communication threshold is only with the priority network P _pr , where the threshold P _{pr is} greater R _2c threshold.

5. If the threshold communication only with the priority network _pr P is not exceeded, and the threshold simultaneous communication with the priority and non-priority networks R _2c exceeded, then in AU again with a period T ₁ compare output signal of the BS priority network F _with thresholds P and P _{2c etc.} .

6. If the threshold for simultaneous communication with the priority and non-priority networks P _{2s is} not exceeded for a time longer than the specified interval T _o2s , then only the non-priority network will communicate with the BS.

7. If the communication threshold with only the priority network P _{pr is} exceeded for a time longer than the specified interval T _pr , the speakers only communicate with the BS of the priority network and compare the signal strength of the BS of the priority network R _with the threshold T ₂ with the threshold of simultaneous communication with the priority and non-priority networks Р _2с and with a communication threshold only with priority network Р _пр .

8. If the threshold communication network only with the priority P _ave exceeded or less than a period of time T, the smaller _vyh.pr predetermined interval T, then again on the AC with a period T ₂ compares power P BS priority network signal _with a threshold simultaneous communication with a priority and non-priority networks P _2s and a communication threshold only with the priority network P _pr until the signal power of the neighboring BS of the priority network is less than the threshold P _pr and more than the threshold P _2c for a time T equal to or greater than the specified interval T _output.pr .

9. If the signal power of the neighboring BS of the priority network P _s is less than the threshold P _pr and more than the threshold P _2s for a time T longer than the specified interval T _output , then the speakers are connected to the BS of the neighboring non-priority network and communicate simultaneously with the base priority and non-priority stations, networks, and then again at the plant with a period T ₁ compared to the signal power P BS priority network _with a threshold simultaneous communication with the priority and non-priority networks and P _2c thresholding network connection with priority P _ave.

Operations 4, 5, 6, and 7 make it possible to ensure reliable transfer of AS service from a non-priority network BS to a priority network BS under fading conditions. The AC service transfer from the BS of the non-priority network to the BS of the priority network is performed through an intermediate state, when the AC, when the threshold is exceeded P _2c for a time longer than the specified interval T _2s , simultaneously communicates with the base stations of the priority and non-priority networks. In the case of false exceeding of the threshold P _2c due to the influence of fading, the presence of the AC connection with the base stations of the priority and non-priority networks reduces the time for the reverse transition from simultaneous communication with the base stations of the priority and non-priority networks to communication only with the BS of the non-priority network. In practice, the reverse transition is performed without delay. Thus, the frequency of ″ ping pong ″ is reduced.

Operations 8 and 9 make it possible to ensure reliable transfer of AS service from a priority network BS to a non-priority network BS under fading conditions. Threshold establishing network connection with priority P _ave smaller threshold output from the network F _O, since the decrease in power P BS priority network _signal to less than the threshold P, _etc., for a time greater than a predetermined interval T _vyh.pr, speakers simultaneously supports communication with base stations of priority and non-priority networks. In the case of false under the influence of the fading signal reduction of the signal strength of the BS of the priority network P _s to a value lower than the threshold P _pr , the presence of the connection of the speakers with the base stations of the priority and non-priority networks reduces the time of the reverse transition from simultaneous communication with base stations of the priority and non-priority networks to communication with BS priority network. In practice, the reverse transition is performed without delay. Thus, the frequency of ping-pong is reduced. The predetermined time interval T _vyh.pr greater than a predetermined time period T _out, since neighbor BS signal with decreasing priority network power P _s to a value less than threshold P, _etc., AU concurrently communicates with base stations of a priority and non-priority networks. Therefore, to verify the reliability (reliability) of the AC service transfer in the conditions of fading, it is possible to increase the time interval T _out . Increasing the time interval T _out.pr improves the handover procedure of the speaker system and its reliability (the frequency of "ping-pong" decreases).

In the method, when changing the AU from the BS non-priority network to the BS priority network, establish a connection with the BS priority network and simultaneously communicate with base stations of the priority and non-priority networks from when the power signal BS priority network P _c exceeds the threshold simultaneous communication with a priority and non-priority networks P _2c for a time longer than a specified interval T _2c , and until the BS signal strength of the priority network P _s becomes greater than the specified communication threshold only with the priority network P _pr for a time greater than a given interval T _pr Introduction of additional simultaneous communication condition with the base stations AU priority and non-priority networks defined by four parameters R _{2c, 2c} T, P and T _{Ave Ave,} allows, if fading effects with a high degree of reliability to transition from the non-priority network BSs to the BS priority network.

In the proposed method, when switching the AC from the BS of a priority network to the BS of a non-priority network, the speakers establish communication with the BS of the non-priority network and simultaneously communicate with the BS of the priority and non-priority networks until the signal power of the neighboring BS of the priority network R _s is less than the threshold communication only with the priority network P _pr and more than the threshold for simultaneous communication with priority and non-priority networks P _2s for a time T greater than the specified interval T _out . Introduction of additional simultaneous communication condition with the base stations AU priority and non-priority networks defined by four parameters R _{2c, 2c} T, P and T _{ave vyh.pr} allows fading when exposed to a high degree of reliability to transition from the priority network BSs to the BS non-priority network .

Thus, in order to reduce the ping-pong frequency when transferring AC service between base stations of two different cellular networks, an intermediate state of simultaneous communication of ACs with base stations of priority and non-priority networks, defined by two thresholds P _2c , P _CR for signal power of base station P, is introduced _{with a} priority network and four time parameters T _2s , T _{output 2s} , T _pr and T _output . defining time intervals for comparing the signal power of the base station of the priority network with the specified two thresholds.

Therefore, the inventive method allows to solve the problem - to improve the quality and reliability of communication during the transfer of service between speakers between base stations of two different cellular networks.

The inventive transmission service of the subscriber station allows you to fully implement all the features of the proposed method, has novelty and allows you to get a new technical effect, namely to improve the quality and reliability of communication during the transfer of service AC. The technical effect is achieved by introducing new blocks - the first, second and third logical elements NOT, the third, fourth and fifth logical elements AND, the third and fourth counters, the first, second and third logical elements OR, which together with the above connections provide quality and the reliability of communication during the transfer of service AC.

Further, the description of the invention is illustrated by examples and graphic materials.

Figure 1 is a structural diagram of a prototype device.

Figure 2 shows a graph diagram of the state of the speaker and the transitions between them.

Figure 3 is a structural diagram of a subscriber station.

Figure 4 is a structural diagram of the inventive device.

The subscriber station (Fig. 3) is shown as an example of execution and comprises an antenna 21, a splitter 22, a receiver of BS signals of a non-priority network 23, a transmitter 24, a receiver of BS signals of a priority network 25 and a control unit 26 comprising a control unit 27 and a handover unit of a subscriber station 28, while the first input and output of the antenna 21 are respectively the input and output of the device, the second input and output of the antenna 21 are connected respectively to the first input and output of the splitter 22, the second and third outputs of the splitter 22 are connected respectively With the first inputs of the BS signal receiver of the non-priority network 23 and the BS signal receiver of the priority network 25, the output and the second input of the BS signal receiver of the non-priority network 23 are connected respectively to the first input and the first output of the control unit 27, which forms the first input and output of the control unit 26, the second and third inputs of the control unit 27, forming respectively the second and third inputs of the control unit 28, are connected respectively to the first and second outputs of the signal receiver BS priority network 25, the second input of which It is connected to the second output of the control unit 27, which forms the second output of the control unit 26, respectively, the third and fourth outputs of the control unit 27 are connected respectively to the first and second inputs of the AC 28 transmission service node, the first and second outputs of which are connected to the fourth and fifth inputs of the node, respectively control 27, the fifth and sixth outputs of which, respectively forming the third and fourth outputs of the control unit 26, are connected respectively to the first and second inputs of the transmitter 24, the output of which is connected to orym input splitter 20.

The inventive transmission service of the subscriber station (figure 4) contains the first 1 and second 2 blocks of comparison with the threshold, the first 3 and second 4 logic elements And, the first 5 and second 6 counters, a clock 7, the first 8 and second 9 triggers, the inputs of the first 1 and second 2 comparison blocks with a threshold are combined to form the first input of the device, the output of the first comparison block with threshold 1 is connected to the first input of the first logical element And 3, the output of the second comparison block with threshold 2 is connected to the first input of the second of the element And 4, the second inputs of the first 3 and second 4 logical elements And are combined to form a second input of the device, the output of the clock 7 is connected to the first inputs of the first 5 and second 6 counters, the output of the second counter 6 is connected to the first input of the second trigger 9, the output of which is the second output of the device, and the output of the first trigger 8 is the first output of the device, according to the invention, the device further comprises a first 10, second 11 and third 12 logic elements NOT, the third 13, fourth 14 and fifth 15 logic elements you And, the third 16 and fourth 17 counters, the first 18, second 19 and third 20 logical elements OR, while the output of the first logical element And 3 is connected to the input of the first logical element NOT 10 and the second input of the second counter 6, the output of the second logical element And 4 is connected to the input of the second logical element HE 11 and the first input of the third logical element AND 13, the output of the first logical element HE 10 is connected to the second input of the third logical element AND 13, the output of which is connected to the second input of the first counter 5 and the first input m of the fourth logical element AND 14, the output of the second logical element NOT 11 is connected to the first inputs of the first 18 and third 20 logical elements OR and the fifth logical element And 15, the first inputs of the third 16 and fourth 17 counters are connected to the output of the clock generator 7, the output of the first counter 5 is connected to the first input of the second logic element OR 19 and the second input of the third logic element OR 20, the second input of the second logic element OR 19 is connected to the output of the second counter 6, the third inputs of the second 19 and the third 20 logical gates OR are connected to the output of the third counter 16, the output of the fourth counter 17 is connected to the second input of the first logical gate OR 18 and the fourth input of the third logical gate OR 20, the output of which is connected to the second input of the second trigger 9, the outputs of the first 18 and second 19 logical elements OR are connected respectively to the first and second inputs of the first trigger 8, the output of the first trigger 8 is connected to the second inputs of the fourth 14 and fifth 15 of the logical elements AND, the output of the fourth logical element And 14 connected to the second input of the third counter 16, the output of the fifth gate AND 15 is connected to the second input of the fourth counter 17, the output of the second trigger 9 is connected to the input of the third logic gate HE 12 and the third input of the fifth logic gate AND 15, the output of the third logic gate NOT 12 is connected with the third input of the fourth logical element And 14.

Carry out the inventive method of transferring service between the base stations of two different cellular networks, one of which is a priority in relation to the second, as follows.

Consider figure 2, which is a graph diagram of the possible states of the speakers and the transitions between them.

Each state of the AC is determined by the organization of communication between the AC and base stations of the priority and non-priority networks (support of communication with the BS of the priority network, support of communication with the BS of the non-priority network, simultaneous support of communication with the base stations of the priority and non-priority networks), the power of the received signal of the BS of the priority network and the condition transition to this state.

Figure 2 shows the possible state of the speaker and the transitions between

them, namely:

The first state is the communication of the AU with the BS of a non-priority network;

2a - communication of the AU with a BS of a non-priority network (when T <T _2s ),

2b - communication of the AU with the BS of both networks (when T> T _2s );

3a - communication of the AU with a BS of a non-priority network (when T> T _out.2s ),

3b - communication of the AU with the BS of the priority network (when T> T _pr );

4a - communication of the AU with the BS of the priority network (when T <T _out.pr );

4b - communication of the AU with the BS of both networks (when T> T _out.pr ).

In the first state, the signal strength of the BS of the priority network P _{c is} less than the communication support threshold simultaneously with the priority and non-priority networks P _2s . If the signal power of the neighboring BS of the priority network P _s does not exceed the threshold for simultaneous communication with priority and non-priority networks P _2c or exceeds it for a time T shorter than the specified interval T _2c : T <T _2c (state 2a), then the signal power is compared on the AC the neighboring BS of the priority network P _with a threshold of P _2s until the signal of the neighboring BS of the priority network P _c exceeds the specified threshold P _2c for a time T longer than the specified interval T _2s (T> T _2s ). If the signal power of the neighboring BS of the priority network P _s exceeds the threshold for simultaneous communication with the priority and non-priority networks P _2c for a time longer than the specified time interval T _2s (T> T _2s ), the speakers establish communication with the BS of the neighboring priority network and communicate simultaneously with base stations of priority and non-priority networks (state 2b).

After establishing communications speaker with BS priority network to AC with a period T ₁ compare output signal of the BS priority network F _with a simultaneous communication threshold to the priority and non-priority networks P _2c and the threshold communication only with the priority network P _ave, wherein the threshold P _ave greater than the threshold P _2c .

If the communication threshold only with the priority network P _{pr is} not exceeded, and the threshold of simultaneous communication with the priority and non-priority networks P _{2c is} exceeded, then the signal strength of the BS of the priority network P _with the thresholds P _2c and P _{pr is} compared with the period T ₁ again.

If the threshold for simultaneous communication with priority and non-priority networks P _{2s is} not exceeded for a time longer than the specified interval T _o2s (T> T _oo2s ), then only the non-priority network will communicate with the BS (state 3a).

If the threshold is due to the priority communication P _ave is exceeded for a time greater than a predetermined interval T _ave (T> T _pr) for AC communicating only with BS priority network, and with a period T ₂ compared output signal of the BS priority network F _with a threshold simultaneous communication with the priority and non-priority networks P _2s and with the communication threshold only with the priority network P _pr (state 3b).

If the threshold is only communication with the network priority P _ave exceeded or less than a period of time T, the smaller _vyh.pr predetermined interval T (T _<vyh.pr) (4a condition), then again with the AC period T ₂ compared output signal BS priority network P _with a threshold for simultaneous communication with priority and non-priority networks P _{2 s} and a communication threshold only with priority network P _pr until the signal power of the neighboring BS of the priority network is less than threshold P _pr and more than threshold P _2s for time T equal to or greater than the specified interval T _{o. pr} : T> T _out.pr (state 4b).

For a better understanding of the proposed method, consider its implementation on devices (Fig.3 and 4).

Figure 3 shows the structural diagram of the speaker, which determines the location of the transmission device in the composition of the speaker and the interaction of this device with other units.

When performing a handover of the AC between the base stations of two different cellular networks on the AC served by the source BS of the non-priority network, the receiver of the signals of the BS of the priority network 25 by the signal received from the antenna 21 through the splitter 22 performs the procedure of determining the neighboring BS of the priority network (search for the nearest base stations corresponding network and determining the BS with the highest power).

If the BS of the priority network is detected, then from the first and second outputs of the receiver of the signals of the BS of the priority network 25 to the second and third inputs of the control unit 27, respectively, the detection signal of the BS of the priority network is generated, which is generated by the receiver 25 when the BS signal of the priority network is detected, and the signal strength of the BS priority network. From the third and fourth outputs of the control unit 27, the detection signal of the BS of the priority network and the signal strength of the signal of the BS of the priority network are received at the first and second inputs of the handoff unit AC 28.

The organization of communication between the AS and the base stations of the priority and non-priority networks is determined in the handover device of the AC (support for communication with the BS of the priority network, support for communication with the BS of the non-priority network, simultaneous support for communication with the base stations of the priority and non-priority networks).

If the AU communicates with the BS of a non-priority network, from the output 1 of the transmission device of the AC 28 to the input 4 of the control node 27 with the level of a "logical unit", a signal is received for establishing communication with the BS of a non-priority network. According to this signal, from the first output of the control unit 27 to the second input of the signal receiver of the BS of a non-priority network 23, a signal is received for establishing communication with a BS of a non-priority network.

If the AS simultaneously communicates with the base stations of the priority and non-priority networks, from the output 1 and the output 2 of the AC 28 handover device to the input 4 and input 5 of the control unit 27 with the level of “logical unit” signals are received for establishing communication with the BS of the priority network and establishing communication with a BS of a non-priority network, respectively. Based on these signals, from the first output of the control unit 27 to the second input of the signal receiver of the BS of a non-priority network 23, a signal of establishing communication with the BS of a non-priority network is received and from the second output of the control unit 27 to the second input of the receiver of signals of a BS of a priority network 25 a signal of communication with a priority network BS .

If the AU is in communication with the base station of the priority network, from the output 2 of the handover device AC 28 to the input 5 of the control node 27 with the level of "logical unit" receives a signal for establishing communication with the BS of the priority network. According to this signal, from the second output of the control unit 27 to the second input of the signal receiver of the BS of the priority network 25, a signal is received for establishing communication with the BS of the priority network.

The establishment of communication with a neighboring BS, both priority and non-priority networks, includes synchronization with the signal of the neighboring BS and registration of the AC on this BS. After establishing the AS communication with the BS of the corresponding network, it becomes possible to transfer useful information between the AS and the BS.

If a signal of establishing communication with a neighboring BS of a corresponding network is received at a receiver of BS signals of a priority network 25 or a receiver of signals of a BS of a non-priority network 23, and the procedure for determining a neighboring BS of this network is not performed, then this receiver first performs the procedure of determining a neighboring BS of the corresponding network, and then sets connection with her. In this case, the receiver of the BS signals of the non-priority network 23, according to the signal received from the antenna 21 through the splitter 22, performs the procedure of determining the neighboring BS of the non-priority network and, after the BS of the non-priority network is detected, the detection signal of the BS of the non-priority network comes from the output of the BS signal receiver of the non-priority network 23 to the first input of the node management 27.

The control unit 26 consists of a control unit 27 and a handover unit AC 28. Both of these devices can be implemented on the basis of a single microprocessor.

From the fifth and sixth outputs of the control unit 27 to the first and second inputs of the transmitter 24 receives the signal to turn on the transmitter and the transmitted information

After determining the neighboring BS priority network, the second and first inputs of the AC transmission device (Fig. 4) receive the detection signal of the BS of the priority network and the signal strength of the BS of the priority network.

From the first input of the device, the signal strength of the BS signal of the priority network is supplied to the first inputs of the first 1 and second 2 blocks of comparison with the threshold.

In the first comparison block with threshold 1, the signal power of the neighboring BS of the priority network is compared with a given communication threshold with only the priority network P _ave .

In the second comparison block with threshold 2, the signal power of a neighboring BS of a priority network is compared with a predetermined threshold for simultaneous communication with priority and non-priority networks P _2c .

When a priority network BS detection signal is received at the second input of the device, the output signals of the first 1 and second 2 comparison blocks with a threshold are received respectively at the first inputs of the first 3 and second 4 logic elements I.

If the signal power of a neighboring BS of a priority network does not exceed the threshold for simultaneous communication with priority and non-priority networks P _2c , then a signal is output from the output of the second logical element NOT 11, which sets the first trigger 8 to the “zero state” through the first logical element OR 18 and the third logical element OR 20 sets the second trigger 9 to "single state" and thus form a signal for establishing communication with a BS of a non-priority network, which is supplied to the second output of the device.

If the signal power of the neighboring BS of the priority network exceeds the threshold for simultaneous communication with the priority and non-priority networks P _2s and does not exceed the communication threshold only with the priority network P _pr , then the signals from the output of the second logical element And 4 and the output of the first logical element NOT 10 the first and second inputs of the third logical element And 13, which generates a signal that controls the first counter 5. When a control signal is received from the output of the third logical element And 13 to the second input of the first counter 5, the first counter counts the pulses coming from the output of the clock pulse generator (GTI) 7 to the first input of the first counter 5. If the control signal does not arrive, counter 5 is set to "zero state". If for a time equal to or greater than the specified time interval T _2s , the signal power of the neighboring BS of the priority network exceeds the threshold for simultaneous communication with priority and non-priority networks P _2s and does not exceed the communication threshold only with priority network P _pr , then the output of the first counter 5 a signal that, through the second OR gate, sets the first trigger 8 to the "single state" and through the third OR gate 20 sets the second trigger 9 to the "single state", and thus forms the signal Communication with base stations of the priority network and non-priority network, which are received at the first and second outputs of the device.

If the signal power of the neighboring BS of the priority network exceeds the communication threshold only with the BS of the priority network R _pr , then the control signal is supplied from the output of the first logical element And 3 to the second input of the second counter 6. If there is a control signal, the second counter 6 counts the pulses from the clock generator (GTI) 7. When the control signal is turned off, the second counter 6 is set to "zero". If for a time equal to or greater than the specified time interval T _pr , the signal power of the neighboring BS of the priority network exceeds the communication threshold only with the priority network P _pr , then a signal is received from the output of the second counter 6, which sets the first trigger 8 through the second logical element OR 19 in the "single state" and the second trigger 9 in the "zero state", and thus generates a signal for establishing communication with the BS priority network, which is fed to the first output of the device.

If the AU communicates with the BS of the priority network, and the signal power of the neighboring BS of the priority network exceeds the threshold for simultaneous communication with the priority and non-priority networks P _2c and does not exceed the communication threshold only with the priority network P _pr , then from the output of the third logical element And 13, from the output the first trigger 8 and the output of the second trigger 9 through the third logical element HE 12 receives signals at the inputs of the fourth logical element And 14, which generates a signal that controls the third counter 16. In the presence of a control signal and a third counter 16 counts the pulses coming from the clock generator (GTI) 7. When turning off the third control signal the counter 16 is set to "zero state". If for a time equal to or greater than the specified time interval T _output.pr , the signal power of the neighboring BS of the priority network exceeds the threshold for simultaneous communication with priority and non-priority networks P _2s and does not exceed the communication threshold only with priority network P _pr , then the output of the third counter 16, a signal is received which, through the second logical element OR 19, sets the first trigger 8 to "single state" and through the third logical element OR sets the second trigger 9 also to "single state", and thus form signals for establishing communication with base stations of the priority network and non-priority network, which are received at the corresponding outputs of the device.

If the AU communicates with the base stations of the priority network and the non-priority network, and the signal power of the neighboring BS of the priority network does not exceed the threshold for simultaneous communication with the priority and non-priority networks Р _2с , then from the output of the second logical element NOT 11, from the output of the first trigger 8 and from the output the second trigger 9 receives signals at the inputs of the fifth logical element And 15, which generates a signal that controls the fourth counter 17. If there is a control signal, the fourth counter 17 counts the pulses from the output of the gene Rathore clock (GTI) 7. When turning off the fourth control signal the counter 17 is set to "zero state". If for a time equal to or greater than a specified time interval T _o2s , the signal power of a neighboring BS of a priority network does not exceed the threshold for simultaneous communication with priority and non-priority networks P _2c , then a signal is output from the output of the fourth counter 17, which sets through the first OR gate 18 the first trigger 8 to "zero state" and through the third logical element OR sets the second trigger 9 to "single state", thus forming a signal for establishing communication with a BS of a non-priority network, which falls on the second output of the device.

Thus, the claimed method and device for its implementation can solve the problem - to improve the quality and reliability of communication during the transfer of service between the base stations of two different cellular networks.

The inventive device transfer service AC is industrially applicable, not difficult to implement, because uses devices known in radio engineering.

Bibliography

1.K. Pahlavan, P. Krishnamurthy, A. Hatami, M. Ylianttila, J.P. Makela, R.Pichna, Jari Vallstrom. "Handoff in hybrid mobile data networks" IEEE Personal Communication, vol. 7, issue 2, Apr. 2000.

2. YE Min-hua, LIU Yu, ZHANG Hui-min THE MOBILE IP HANDOFF BETWEEN HYBRID NETWORKS PIMRC 2002, The 13th IEEE International Symposium on Personal, Indoor and Mobile Communications, September 15-18, 2002, Lisboa, Portuga www.ctr .kcl.ac.uk / Private / Mischa / PIMRC2002 / papers / cr1002.pdf.

3. US patent No. 5,999,816.

4. YE Min-hua, LIN Yu, ZHANG Hui-min THE MOBILE IP HANDOFF BETWEEN HYBRID NETWORKS IEEE Personal Indoor and mobile Communication (PIMRC 2002).

Claims (3)

1. A method of handing off a subscriber station between base stations of two different cellular networks, one of which is a priority over the second, in which a neighboring priority base station of a priority network is determined at a subscriber station (AC) served by a source base station (BS) of a non-priority network which consists in the fact that the AC power signal is compared neighbor BS priority network F _with a threshold support simultaneous communication connection with the priority and non-priority networks R _2c, if the signal strength neighbor s the BS priority network P _c does not exceed the threshold of simultaneous communication with the priority and non-priority networks P _2c or greater than a period of time T, the smaller the set interval T _2c, then SS compares power neighboring BSs priority network P signal _with a threshold P _2c as while the signal of the neighboring BS of the priority network P _s exceeds the specified threshold P _2s for a time longer than the specified interval T _2s , if the signal power of the neighboring BS of the priority network P _s exceeds the threshold for simultaneous communication with the priority and non-priority networks P _2c for If the time is longer than the specified interval T _2s , the speakers establish communication with the BSs of the neighboring priority network and communicate simultaneously with the base stations of the priority and non-priority networks, after the connection between the speakers and the BSs of the priority network on the speakers with a period T ₁ , the signal strength of the BSs of the priority network is compared P _with a threshold simultaneous communication with the priority and non-priority networks and P _2c threshold communication only with the priority network P _ave, wherein P _ave threshold greater than the threshold P _2c, if the threshold communications network only with the priority P _ave is not exceeded, and pore simultaneous communication with the priority and non-priority networks R _2c exceeded, then in AU again with a period T ₁ compares the priority network capacity BS signal F _with thresholds P _2c and P, _etc., if the threshold simultaneous communication with the priority and non-priority networks P _2c is not exceeded during time greater than a predetermined interval T _vyh2s, then SS communicate with the BS only non-priority network, if the threshold due to a priority network P _ave is exceeded for a time greater than a predetermined interval T _Ave, for AS communicating only with BS priority network and a re iodine T ₂ compared output signal BS priority network F _with a simultaneous communication threshold to the priority and non-priority networks R _2c and a communication threshold only priority network P, _etc., if the threshold communication only with the priority network P _ave exceeded or less than a time T less than a predetermined interval T _vyhpr, then again with AC period T ₂ compared to the signal power P BS priority network _with a simultaneous communication with a threshold priority and non-priority networks and R _2c threshold communication only with the priority network P _etc. as long as powerfully be adjacent BS priority esti signal is less than the threshold F _ave and larger than the threshold R _{2 c} for a time T equal to or greater than a predetermined interval T _{out, etc.,} if the priority network capacity neighbor BS signal P _to be less than the threshold F _ave and greater than the threshold P _2c If time T is longer than the specified interval T _{o / v} , then the communication with the BS of the neighboring non-priority network is established on the AS and the communication is maintained simultaneously with the BS of the priority and non-priority networks, after which the signal strength of the BS of the priority network R _{s is} compared again with the period T ₁ orogs simultaneous communication with the priority and non-priority networks R _2c and threshold establishing communication with a network priority P _ave. 2. The method according to claim 1, characterized in that the neighboring BS of the priority network is determined at the AS by searching for the BS signals of neighboring cells of the priority network in a given time-frequency domain, remembering the signal strengths of the detected signals of neighboring BS cells of the priority network, averaging them, choosing a signal with a maximum average power, deciding that the selected signal is a signal of a neighboring BS of a priority network, remembering the time-frequency position of a signal of a neighboring BS of a priority network. 3. A handover device of a subscriber station between base stations of two different cellular networks, one of which is a priority, as a part of a subscriber station, containing the first and second blocks of comparison with a threshold, the first and second logic elements And, the first and second counters, a clock , the first and second triggers, while the inputs of the first and second comparison units with a threshold are combined, forming the first input of the device, which is the signal input of the signal strength value of the signal of the base station priority network, the output of the first comparison unit with a threshold is connected to the first input of the first logical element And, the output of the second comparison unit with a threshold is connected to the first input of the second logical element And, the second inputs of the first and second logic elements And are combined, forming the second input of the device, which is the input signal of the detection of the base station of the priority network, the output of the clock is connected to the first inputs of the first and second counters, the output of the second counter is connected to the first input of the second trigger, the output of which is the second output of the device on which a signal is established to establish communication with the base station of the non-priority network, and the output of the first trigger is the first output of the device on which the signal is formed to establish communication with the base station of the priority network, characterized in that the first, second and third logic elements NOT, the third, fourth and fifth logical elements AND, the third and fourth counters, the first, second and third logical elements OR, while the output of the first logical element AND is connected to the input of the first logical element NOT and the second input of the second counter, the output of the second logical element AND is connected to the input of the second logical element NOT and the first input of the third logical element AND, the output of the first logical element is NOT connected to the second input of the third logical element AND, the output of which is connected to the second the input of the first counter and the first input of the fourth logical element AND, the output of the second logical element is NOT connected to the first inputs of the first and third logical elements OR and the fifth log element And, the first inputs of the third and fourth counters are connected to the output of the clock generator, the output of the first counter, the signal at the output of which is generated if, for a time equal to or greater than the specified time interval T, the power of the base station of the priority network exceeds the threshold for simultaneous communication with priority and non-priority networks, connected to the first input of the second logical element OR and the second input of the third logical element OR, the second input of the second logical element OR the second counter, the signal at the output of which is generated if, for a time equal to or greater than the specified time interval T, the power of the base station of the priority network exceeds the communication threshold with the priority network, the third inputs of the second and third logical elements OR are connected to the output of the third counter, the signal the output of which is formed if, for a time equal to or greater than a specified time interval T, the power of the base station of the priority network exceeds the threshold for simultaneous communication with the priority and non-priority network and does not exceed the threshold of communication with the priority network, the output of the fourth counter, the signal at the output of which is generated, if for a time equal to or greater than the specified time interval T, the power of the base station of the priority network does not exceed the threshold of simultaneous communication with priority and non-priority networks, connected to the second input of the first OR gate and the fourth input of the third OR gate, the output of which is connected to the second input of the second trigger, the outputs of the first and second logic elements OR are connected respectively to the first and second inputs of the first trigger, the output of the first trigger is connected to the second inputs of the fourth and fifth logical elements AND, the output of the fourth logical element AND is connected to the second input of the third counter, the output of the fifth logic element And is connected to the second input of the fourth counter, output the second trigger is connected to the input of the third logical element NOT and the third input of the fifth logical element AND, the output of the third logical element is NOT connected to the third input of the fourth of the element And, while the first block comparing with the threshold compares with the threshold of communication with the priority network, the second block comparing with the threshold compares with the threshold of simultaneous communication with priority and non-priority networks.

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