RU98104403A - METHOD AND DEVICE FOR FORMING A CONTROLLING SIGNAL IN DUPLEX MODE WITH TIME-SHARING - Google Patents

Claims (22)

1. A method of switching communication from a multiple access mode in systems with code division multiplexing (CDMA) to an alternative access mode in a communication system with at least one mobile communication device containing a first plurality of base stations providing communication in CDMA mode, wherein the first plurality of base stations are physically grouped together, the second plurality of base stations providing communication in an alternative access mode, the second plurality of base stations surrounding the first set of base stations, forming a boundary group of base stations, which is a subgroup of the second set of base stations, while the boundary of the working area of each base station of the boundary group is adjacent to the boundary of the working area of the base station of the first set of base stations, which consists in transmitting from each base stations of the first set of base stations, the identification control signal and the CDMA call signals in the first frequency band are received intermittently at each base station of the boundary group of base output stations, the identification control signal transmitted by one of the first set of base stations, the absolute system time estimate is determined from the received identification control signal, the identification control signal, consistent with the specified absolute time estimate, in the first frequency band is transmitted from each base station of the boundary group of base stations , and call signals in an alternative access mode in a different frequency band, with each base station of a boundary group of base stations If the receiver receives the identification control signal only during a break in the transmission of the identification control signal, the intensity of each of the identification control signals corresponding to the neighboring group of base stations is measured in the first mobile communication device, and the neighboring group of base stations includes base stations whose working areas are in close proximity to the specified first mobile communication device, take the first control in the first mobile communication device a signal corresponding to the destination base station, the destination base station being a group of border base stations and a group of neighboring base stations, transmitting from the first mobile communication device to the CDMA system controller, at least one base station of the indicated first plurality of base stations informing about receiving the first control signal, and initiate, by means of the CDMA system controller, a switching procedure for the first mobile communication device with the participation of the system controller with al alter native access mode.  2. The method according to claim 1, further comprising transmitting information from the system controller with an alternative access mode to the CDMA system controller for operating the first mobile communication device in said alternative access mode, and transmitting said information for operating in the alternative access mode to the first mobile device communication through at least one base station of a first plurality of base stations.  3. The method according to claim 1, further comprising transmitting from each base station of an adjacent group of base stations a synchronization channel signal in said first frequency band.  4. The method according to claim 3, in which the signal of the synchronization channel contains an indication of the minimum version level supported by the indicated base station, and this indication indicates a version level incompatible with the first mobile communication device.  5. The method of claim 1, wherein each base station of a first plurality of base stations containing several sectors transmits different identification control signals from each of several sectors, and each base station of a boundary group of base stations containing several sectors transmits an identical control signal in each of several sectors, the border of the working area of which is adjacent to the working area corresponding to the base station of the first set of base stations.  6. The method according to claim 1, in which one of the base stations of the boundary group of base stations contains several sectors, the border of the working area of which is adjacent to the working area corresponding to the base station of the first set of base stations, and the specified one of the base stations of the boundary group of base stations determines only one estimate of absolute system time.  7. The method according to claim 1, wherein said intermittent reception is random.  8. The method according to claim 1, wherein said discontinuous reception is pseudo-random in nature.  9. The method according to claim 1, in which when determining the absolute system time estimates from a received identification control signal, an input delay time signal on a ground path characterizing a transmission delay time from said base station corresponding to a received identification control signal and a receiving base station is demodulated the received identification control signal for determining the current absolute time estimate, compare the absolute time estimate with the current absolute time estimate yutnogo time to obtain the error signal, and adjusting the control signal received identification according to the error signal.  10. The method according to claim 1, in which each of the identification control signals contains an identical sequence of elements of the pseudo-noise code, a time offset is used to distinguish between each of the identification control signals, an absolute time estimate is used to match identical sequences of elements of the pseudo-noise code transmitted from each a base station of a group of boundary base stations with respect to an identical sequence of elements of a pseudo-noise code transmitted from the first group of base stations.  11. A cellular communication system for communicating with at least one mobile communication device, comprising a first plurality of base stations physically grouped together to provide multiple access communication signals in code division multiple access (CDMA) systems, each base station of a first plurality base stations transmits an identification control signal, and the boundary group of base stations, which is a subgroup of the second set of base stations, to provide communication with alternative access mode, and the second set of base stations surrounds the indicated group of the first set of base stations, the boundary of the working area of each base station of the boundary group of base stations is adjacent to the boundary of the working area corresponding to the base station of the first set of base stations, and each base station of the boundary group of base stations contains search, demodulation and filtering schemes intermittently performing demodulation and interruption during transmission of at least one of the identifying controls signal transmitted by each base station of the first set of base stations to obtain an indication of universal time, and a control signal generator that generates a control transmission signal during a break in the operation of search, demodulation and filtering circuits.  12. The cellular communication system according to claim 11, in which the control signal generator generating the transmission control signal comprises a channel 1 reduced code generator that takes universal time and generates a channel extension sequence 1 with a time shift, a first baseband filter receiving the extension sequence 1 channel and forming a filtered channel extension 1, the first mixer modulating the filtered channel 1 extension and forming a modulated 1 output signal, Q channel abbreviated code generator, which takes universal time and generates the Q channel extension sequence with a specified time offset, a second main-band filter that receives the Q channel extension sequence and generates a filtered Q channel extension sequence, and a second mixer that modulates the filtered extension sequence Q channel and generating a modulated output Q signal, an adder summing the modulated output 1 and Q signals to obtain I am the total modulated signal, and a means of upconversion and amplification, receiving the specified total modulated signal and generating a control signal for transmission.  13. The cellular communication system of claim 11, wherein the at least one base station of the first plurality of base stations comprises several sectors, each sector of the at least one base station transmitting a unique identification control signal, and at least one boundary station group contains several sectors, each sector of at least one base station in the boundary group, transmitting a signal identical to the control signal transmission.  14. The cellular communication system of claim 11, wherein the at least one base station of the boundary group comprises a second control signal generator generating a second control signal for transmission having a time offset offset from a time offset of said control signal generator.  15. The cellular communication system according to claim 11, in which the search, demodulation and filtering schemes further comprise a demodulator summing the calibrated delay constant and the current measurement of the shift of the control signal to obtain a current absolute time indication, a comparator comparing the indicated absolute time indication with universal time , to receive an error signal, and a variable time obtaining circuit that corrects the universal time in accordance with the error signal.  16. A method of switching communication from a multiple access mode in systems with code division multiplexing (CDMA} to an alternative access mode in the system to provide communication with at least one mobile communication device containing a first plurality of base stations providing communication in CDMA mode, wherein said first plurality of base stations are physically grouped together, a second plurality of base stations providing communication in an alternate access mode, the second plurality of base stations being surrounded presses the first set of base stations, thereby forming a boundary group of base stations, which is a subgroup of the second set of base stations, and the boundary of the working area of each base station of the boundary group is adjacent to the boundary of the working area corresponding to the base station of the first set of base stations, which consists in transmitting from each base station of the first plurality of base stations, an identification control signal and CDMA call signals in the first frequency band are received intermittently at each base station and the boundary group of base stations, the identification control signal transmitted by one of the first plurality of base stations determines the absolute-system time estimate from the received identification control signal, and the identification control signal matched with the specified absolute time estimate is transmitted intermittently from each base station of the boundary group of base stations , in said first frequency band, and call signals in an alternative access mode in a different frequency band, with each base station tion boundary base station group receives the identification command signal only during a break in the transmission of an identification control signal.  17. The method according to clause 16, in which one of the base stations of the boundary group of base stations contains several sectors, the border of the working area of which is adjacent to the working area corresponding to the base station of the first set of base stations, and the specified one of the base stations of the boundary group of base stations determines only one estimate of absolute system time.  18. The method of claim 16, wherein said discontinuous reception is random.  19. The method of claim 16, wherein said discontinuous reception is pseudo-random.  20. The method according to clause 16, in which when determining the absolute system time estimates from the received identification control signal, a delay time on the ground path characterizing a transmission time delay from the indicated base station corresponding to the received identification control signal and the receiving base station is received, the received identification is demodulated control signal for determining the current absolute time estimate; compare the absolute time estimate with the current absolute time estimate change to receive the error signal, and adjust the received identification control signal in accordance with the error signal.  21. The method according to clause 16, in which the intermittent reception is deterministic in nature, based on the assessment of the absolute time and the identification number assigned to each base station in the boundary group of base stations.  22. The method according to clause 16, further comprising receiving at least one base station a boundary group of base stations a message signal transmitted by one of the first plurality of base stations when receiving an identification control signal transmitted by one of the first plurality of base stations .