RU2173504C2 - Asymmetric channel distribution for mobile station in multiple-access code-dependent communication network - Google Patents

Abstract

FIELD: communication networks built around multiple-access code-dependent systems. SUBSTANCE: system and method used for distributing channel frequency bandwidth and repetition rate of signal components for direct- and indirect-access channels to maintain asymmetric width of frequency band include mobile-to-base station matching process for selecting repetition rate of signal components and frequency bandwidth for use in direct- and indirect-access channels. EFFECT: enhanced data transmission speed due to maintaining asymmetric channel distribution. 27 cl, 5 dwg

Description

 The present invention relates to a code division multiple access (CDMA) communication system and, more particularly, to a system and method for allocating various frequency bands and repetition frequencies of signal elements for the forward and reverse channels of communication paths.

State of the art
One type of cellular communication system uses a technology known as CDMA (Code Division Multiple Access). In a system of this kind, users are distinguished from one another by means of unique codes assigned to them, while at the same time sharing the same frequency band at the same time. CDMA converts the information to be transmitted into a spread spectrum signal by multiplying this information by a pseudo-random number (PSN). Through this expand the range. A pseudo-random number is the digital part of the data, which actually turns out to be completely random. This MSS is synchronized with the system in the CDMA mobile station using a pilot carrier sent from the base station. The frequency with which the PSC sequence is generated is known as the repetition rate of chip chips. A more detailed description of mdcr and the differences between mdcr, mdrv (time division multiple access) and mdcr (frequency division multiple access) can be found, for example, in Code Division Multiple Access, Communication, February 1990, Fred Baumgartner, which is incorporated herein by reference.

 In FIG. 1 schematically illustrates a CDMA-based communication system comprising a mobile station 10, a base station 20, a reverse communication channel 30, which is an electromagnetic wave communication channel transmitted from the mobile station 10 to the base station 20, and a forward communication channel 40, which represents a communication channel on an electromagnetic wave transmitted from the base station 20 to the mobile station 10.

 Currently used in radio communications, mobile stations have a symmetric bandwidth of the forward and reverse channels and, accordingly, symmetrical repetition frequencies of signal elements. The term "symmetric" means that the frequency bandwidth for the forward and reverse channels is the same and that the repetition frequencies of the signal elements in the forward and reverse directions are the same. The CDMA, III-CDMA standard has recently been proposed in order to adapt high-speed data (VD) communication service to a radio or wireless communication channel. VD service can include various applications, such as Internet access, e-mail service, multimedia, where greater performance is required for the forward channel than for the reverse channel, etc. Many of these services, such as multimedia, require asymmetric bandwidths for the forward and reverse directions. The term “asymmetric” means that the repetition rates of the elements of the MSS signal in the forward and reverse communication channels are different from each other.

In the corresponding CDMA-based communication systems, all mobile stations have a symmetrical bandwidth for the forward and reverse communication channels. The procedure for establishing a call connection between the mobile station and the base station is performed on a symmetric forward and reverse channel. After the call connection setup procedure is completed, the call connection is maintained on the same forward / reverse channel. In FIG. Figure 2 shows the asymmetric distribution of channels for the forward and reverse channels, where F ₀ (frequency of the forward communication channel) is not equal to F ₁ (frequency of the reverse communication channel), and BW ₀ (frequency band of the forward communication channel) is equal to BW ₁ (frequency band of the reverse communication channel) ) Both the establishment and maintenance of the call connection are performed in the frequency range F ₀ , F ₁ .

 There is a need to provide mobile stations with a high data rate communication service by maintaining an asymmetric distribution of the forward and reverse channels.

SUMMARY OF THE INVENTION
In accordance with the present invention, there is provided a system and method for asymmetric distribution of the forward and reverse channels in a communication system based on CDMA. In accordance with the present invention, there is provided a system and method for asymmetrically distributing frequency bands and repetition frequencies of signal elements of the forward and reverse channels.

 In accordance with the present invention, a matching process is also provided between the mobile station and the base station to select the optimal frequency band that should be used by the mobile station to receive information transmitted by the base station.

 In addition, in accordance with the present invention, there is provided a code division multiple access system comprising a base station that maintains a base frequency of signal elements, a signal frequency of elements on a forward communication channel and a signal frequency of elements of a reverse communication channel, and a mobile station in communication with the base station, and the mobile station is in communication with the base station so as to independently adjust the values of the repetition rate of elements Forward channel signal and repetition rate of reverse channel signal elements. The repetition rate of the forward channel signal elements may be less than or equal to the maximum direct value allowed by the base station. The repetition rate of the return channel signal elements may be less than or equal to the maximum reciprocal allowed by the base station. In addition, the repetition rate of the signal elements of the forward channel, the repetition rate of the signal elements of the return channel and the base repetition rate of the signal elements can be equal to each other. The base station may transmit maximum forward and / or reverse values to the mobile station. Additionally, the repetition rate of the forward channel signal elements may be less than or equal to the maximum direct value allowed by the mobile station. In addition, the repetition rate of the return channel signal elements may be less than or equal to the maximum reciprocal allowed by the mobile station. In any case, the mobile station can transmit the maximum forward and / or inverse value to the base station.

 In accordance with the present invention, there is also provided a method for operating a CDMA system, comprising the steps of establishing a call connection with a base station that maintains a basic frequency of the signal elements of the signal, the maximum frequency of the signal elements of the forward channel and the maximum frequency of the signal elements of the reverse channel by transferring the search call to the base station from the mobile station, request from the base station the mobile station the desired frequency of the signal elements of the direct ka Ala, transmitting from the base station to the mobile station the maximum repetition rate of the direct channel signal elements, transmitting to the base station from the mobile station the correct repetition frequency of the direct channel signal elements, transmitting the initial message to the mobile station from the base station and maintaining communication with the base station using the adjusted the frequency of the elements of the signal of the direct channel. When using this method, the corrected repetition rate of the signal elements of the forward communication channel may be equal to the base repetition rate of the signal elements. In addition, the corrected repetition rate of the signal elements of the direct communication channel may be equal to the maximum repetition rate of the signal elements of the forward communication channel.

 In addition, the method of operation of the CDMA system may further comprise the steps of requesting, from the base station, the mobile station the desired repetition rate of the signal elements of the reverse channel, transmitting to the mobile station from the base station the maximum repetition rate of the signal elements of the reverse channel, transmitting the adjusted repetition rate of the elements of the reverse channel signal communication from the mobile station to the base station and communication with the base station using the adjusted sample rate of the sampled signal elements deleterious link. In this case, the corrected repetition rate of the signal elements of the reverse communication channel may be equal to the base repetition rate of the signal elements. In addition, the maximum repetition rate of the signal elements of the reverse communication channel may be equal to the base repetition rate of the signal elements. The base signal element repetition rate can also be equal to the corrected signal element repetition frequency of the forward communication channel and the corrected signal element repetition rate of the reverse communication channel. The basic repetition rate of signal elements may also be equal to the maximum repetition rate of signal elements of the forward communication channel and the maximum repetition rate of signal elements of the reverse communication channel.

 In accordance with the present invention, there is also provided a method for operating a CDMA system comprising the steps of establishing a call connection with a mobile station supporting a base signal element repetition rate, a maximum signal element repetition rate in a forward communication channel, and a maximum signal element repetition rate in a reverse communication channel by performing a basic station search call to the mobile station, the base station request from the mobile station the desired frequency of the signal elements in direct m communication channel, transmitting to the base station from the mobile station the maximum repetition rate of the signal elements of the direct communication channel, transmitting to the mobile station from the base station the corrected repetition rate of the signal elements of the direct communication channel, transmitting the initial message to the base station from the mobile station and communicating with the mobile station using the corrected signal repetition rate of the forward link signal elements. The adjusted repetition rate of the signal elements of the forward channel can be equal to the base repetition rate of the signal elements and / or can be equal to the maximum repetition rate of the signal elements of the forward channel. This method may further comprise the steps of requesting, from the mobile station, the base station, the desired repetition rate of the signal elements of the reverse communication channel, transmitting the base station from the mobile station the maximum repetition rate of the signal elements of the reverse communication channel, transmitting to the mobile station from the base station the correct repetition rate of the signal elements of the reverse communication channel and communicating with the mobile station using the adjusted repetition rate of the reverse channel signal elements. In this case, the base signal element repetition rate may be equal to the adjusted repetition frequency of the signal elements of the reverse communication channel and / or the maximum repetition rate of the signal elements of the reverse communication channel. In addition, the base signal element repetition rate may be equal to the corrected signal element repetition frequency of the forward communication channel and the adjusted element repetition frequency of the reverse communication channel, and / or the maximum repetition rate of the signal elements of the forward communication channel and the maximum repetition rate of the signal elements of the reverse communication channel.

 One of the advantages of the present invention is increased flexibility in the allocation of frequencies in the base station.

 Another advantage of the present invention is the ability to adapt asymmetric high-speed data services, such as multimedia radio applications.

 The present invention also provides the advantage of increased frequency utilization efficiency.

FIG. 1 - communication system based on mdcr, known from the prior art;
FIG. 2 is a graph of amplitude versus frequency of the forward and reverse channels having symmetric frequency bands;
FIG. 3 is a diagram of a typical CDMA-based communication network in accordance with the present invention;
FIG. 4 is a graph of amplitude versus frequency of the frequency distributions of the forward and reverse channels during and after the call connection establishment procedure of the present invention;
FIG. 5 is a flowchart of a process for matching a frequency of elements of a frequency band signal according to the present invention.

 A typical telephone system in which the present invention is implemented is shown in FIG. 3. This system uses CDMA modulation technique for communication between mobile stations, blocks or telephones of the system and central points of cells or base stations. Cellular systems in large cities can have hundreds of central cell stations, serving hundreds of thousands of mobile phones. The use of CDMA technology significantly contributes to an increase in the number of users in systems of this size compared to conventional cellular frequency modulation systems.

 In FIG. 3, a controller 110 and a system switch, also referred to as a mobile telephone switching center (CCTT), typically comprises an interface and a processing circuit for providing system control of a central cell station or base stations. The controller 110 also controls the routing of telephone calls from the public switched telephone network (PSTN) to the corresponding base station for transmission to the corresponding mobile station. Controller 110 also controls the routing of calls from the mobile station through at least one base station to the PSTN. The controller 100 can route calls to mobile users through the respective base stations, since such mobile stations usually do not communicate directly with each other.

 The controller 110 may be connected to base stations using various means, such as leased telephone lines, fiber optic communication channels, or microwave communication channels. It should be appreciated that the controller 110 and system switch can be combined with any number of base stations. In FIG. 3 illustrates three such typical base stations 112, 114, and 116, together with a typical mobile station 118, which includes a cell phone. Arrows 120a through 120b indicate communication channels between base station 112 and mobile station 118. Arrows 122a through 122b indicate communication channels between base station 114 and mobile station 118. Similarly, arrows 124a through 124b indicate communication channels between base station 116 and mobile station 118. .

 The service areas of a central cell or base station or cell location are geographically designed so that the mobile station is usually closest to one cell. When the mobile station is on hold, i.e. when there is no call service, the mobile station constantly monitors the transmission of the pilot signal from the nearest base station. As shown in FIG. 3, pilot signals are respectively transmitted to mobile station 118 by base stations 112, 114, and 116, respectively, on direct communication channels 120b, 122b, and 124b. The mobile station then determines in which cell it is located by comparing the levels of the pilot signals transmitted from these specific cell sites.

 In the example of FIG. 3, the mobile station 118 can be considered closest to the base station 116. When the mobile station 118 initiates a call, a control message is transmitted to the nearest base station — the base station 116. The base station 116, after receiving the call request message, signals the system controller 110 and transmits the number call. System controller 110 then connects the call through the PSTN to the desired receiver.

 According to this invention, mobile stations for high-speed data services should support the asymmetric nature of this service. In other words, these mobile stations must maintain the asymmetry of the forward and reverse communication channels by controlling the repetition frequencies of the signal elements of the mobile station. The repetition frequencies of the signal elements of the mobile station can be adjusted by changing the frequency of the generator of the PSC sequence. A more detailed description of the components of the mobile station is given in Standard TIA / EIA / IS-95A (incorporated herein by reference). The installation of asymmetric forward and reverse channels in accordance with the present invention includes the use of symmetrical forward and reverse channels as a special case. To comply with the standard III-mdcr, the bandwidth for the forward and reverse channels may have values equal to integer multiple values of the base bandwidth. For example, the base bandwidth of an IS-95 based CDMA system is typically 1.2288 MHz. For operations such as soft handoff, mobile stations may use a forward / reverse link combination having, for example, a bandwidth of 1.2288 MHz.

In FIG. 4, representing an example of asymmetric channel allocation, a graph of the channel allocation according to the present invention is shown both during and after the call setup procedure. The bandwidth for bands 210 (forward channel frequency bandwidth is symmetrical) and 220 (reverse channel frequency bandwidth is symmetrical) frequencies that are centered at frequencies F ₀ (initial frequency of the forward communication channel) and F ₁ (initial frequency of the reverse communication channel ) are the same. Bandwidth for bands 230 (forward channel bandwidth - asymmetric) and 240 (reverse channel bandwidth - asymmetric) frequencies that are centered at frequencies F ₂ (corrected frequency of the forward communication channel) and F ₃ (adjusted frequency of the reverse communication channel ), can be different, i.e., asymmetric. The call setup procedure can be performed through the frequency bands 210 and 220 to match the forward / reverse channel bandwidth after the call is established. The repetition rate of the signal elements for each direction (reverse and forward) is agreed between the base station and the mobile station in the frequency bands 210 and 220. The mobile station selects the maximum signal element repetition rate available for each direction in which the selected frequency is supported by the mobile station. The mobile station then sets the selected frequency for both directions for bands 230 (asymmetric bandwidth of the forward communication channel) and 240 (asymmetric bandwidth of the reverse frequency channel. The negotiation process is performed on the bands 210 and 220. At the end of the negotiation, the mobile station transmits a call from frequency bands 210 and 220 to frequency bands 230 and 240. After this transmission operation, the call is supported on frequency bands 230 and 240. If the base station supports only the base frequency of the signal elements (do not change yaemuyu), then the call should be maintained at the first pair of bands 210 and 220 of frequencies.

 In FIG. 5 is a flowchart of a process for matching frequencies of signal elements / bandwidth. At step 305, the mobile station establishes a call connection with a base signal rate such as 1.2288 MHz. At step 310, the mobile station (MS) sends a request to the base station (BS) for the frequency of the signal elements for the forward and reverse channels. At step 315, the MS receives a response from the BS with information about the allowed repetition rates of signal elements for the forward and reverse channels. At step 320, the MS sends an acknowledgment message to the BS. The BS also prepares resources for the corrected repetition frequencies of the signal elements of the forward and reverse channels and sends the initial message to the PS. At step 325, the MS begins to communicate with the BS at the newly assigned frequency of the signal elements for the forward and reverse channels.

 It is obvious that in the present invention can be made various changes, replacements and modifications without changing its essence, as it is set forth in the following claims.

Claims (27)

 1. A code division multiple access (CDMA) system comprising a base station supporting a base signal element repetition rate, a forward channel signal element repetition rate and a reverse signal signal element repetition rate, and a mobile station in electronic communication with said a base station, said mobile station being in communication with said base station so as to asymmetrically control the values of said element repetition rate the signal of the forward communication channel and said repetition rate of the signal elements of the reverse communication channel.  2. The CDMA system according to claim 1, wherein said repetition rate of the signal elements of the forward communication channel is less than or equal to the maximum allowed repetition rate of the signal elements in the forward direction.  3. The CDMA system according to claim 1, wherein said repetition rate of the signal elements of the reverse communication channel is less than or equal to the maximum repetition rate mentioned by the base station of the signal elements in the reverse direction.  4. The CDMA system according to claim 1, in which said repetition rate of the signal elements of the forward communication channel and said repetition rate of the signal elements of the reverse communication channel are equal.  5. The CDMA system according to claim 1, wherein said basic signal element repetition rate, said forward signal signal repetition frequency, and said reverse signal signal repetition rate are equal.  6. The CDMA system of claim 2, wherein said base station transmits to said mobile station a maximum forward frequency of signal elements.  7. The CDMA system according to claim 3, in which said base station transmits to said mobile station the maximum repetition rate of signal elements in the opposite direction.  8. The CDMA system according to claim 1, in which said repetition rate of the signal elements of the forward communication channel is less than or equal to the maximum allowed repetition rate of the signal elements in the forward direction.  9. The CDMA system according to claim 1, wherein said repetition rate of the signal elements of the reverse communication channel is less than or equal to the maximum permissible repetition rate of the signal elements in the reverse direction.  10. The CDMA system of claim 8, wherein said mobile station transmits to said base station a maximum forward frequency of signal elements.  11. The CDMA system according to claim 9, in which said mobile station transmits to said base station a maximum repetition rate of signal elements in the opposite direction.  12. The method of operation of the mdcr system, comprising the steps of establishing a call connection with a base station that supports the base frequency of the signal elements, the maximum frequency of the signal elements of the forward communication channel and the maximum frequency of the signal elements of the reverse communication channel by sending a paging station to the said base station requesting from said base station to said mobile station the desired repetition rate of forward channel signal elements, transmissions and to said mobile station from said base station of said maximum repetition rate of signal elements of a direct communication channel, transmitting to said base station from said mobile station an adjusted repetition rate of elements of a signal of direct communication channel, transmitting to said mobile station from said base station an initial message, maintaining communicating with said base station using said corrected forward link signal rate .  13. The method of operation of the mdcr system according to item 12, in which the aforementioned corrected repetition rate of the signal elements of the forward communication channel is equal to the said base frequency of the repetition of the signal elements.  14. The method of operation of the CDMA system according to item 12, in which the aforementioned corrected repetition rate of the signal elements of the forward communication channel is equal to the aforementioned maximum repetition rate of the signal elements of the forward channel.  15. The method of operation of the CDMA system according to claim 12, further comprising the steps of requesting said base station from said mobile station for a desired repetition rate of signal elements of a reverse communication channel, transmitting to said mobile station from said base station said maximum repetition rate of signal elements of a reverse communication channel, transmitting said base station from said mobile station an adjusted repetition rate of signal elements of the reverse communication channel and maintaining communication with said mentioned base station using said corrected frequency of the elements of the reverse link signal.  16. The method of operation of the mdcr system according to clause 15, in which said adjusted repetition rate of the signal elements of the reverse communication channel is equal to said base repetition rate of the signal elements.  17. The method of operation of the mdcr system according to clause 15, in which said maximum repetition rate of the signal elements of the reverse communication channel is equal to the aforementioned base repetition rate of signal elements.  18. The method of operation of the mdcr system according to clause 15, wherein said basic signal element repetition rate is equal to said corrected signal repetition rate of the forward communication channel signal and said adjusted repetition rate of signal elements of the forward communication channel.  19. The method of operation of the mdcr system according to clause 15, in which said base frequency of the signal elements is equal to the maximum frequency of the signal elements of the forward channel and said maximum frequency of the signal elements of the reverse communication channel.  20. The method of operation of the mdcr system, comprising the steps of establishing a call connection with a mobile station that supports the base signal rate of the signal elements, the maximum signal rate of the signal elements of the forward communication channel and the maximum signal frequency of the reverse signal channel by sending a paging call to the said mobile station to the base station requesting said mobile station by said base station of a desired repetition rate of signal elements of the forward communication channel signal, transmitting if said base station from said mobile station said maximum repetition rate of signal elements of a direct communication channel, said said mobile station from said base station adjusted frequency of repetition of signal elements of a direct communication channel, said said base station from said mobile station started communication and communication with said the mobile station using the corrected repetition rate of the forward channel signal elements.  21. The method of operation of the mdcr system according to claim 20, in which said adjusted repetition rate of the signal elements of the forward communication channel is equal to said base repetition rate of the signal elements.  22. The method of operation of the mdcr system according to claim 20, in which the aforementioned corrected repetition rate of the signal elements of the forward communication channel is equal to the aforementioned maximum repetition rate of the signal elements of the forward channel.  23. The method of operation of the mdcr system according to claim 20, further comprising the steps of requesting said mobile station by said base station for a desired repetition rate of signal elements of a reverse communication channel, transmitting to said base station from said mobile station said maximum repetition rate of signal elements of a reverse communication channel, transmitting to said mobile station from said base station an adjusted repetition rate of signal elements of a reverse communication channel and maintaining communication with said removed by the mobile station, using the aforementioned corrected repetition rate of the signal elements of the reverse communication channel.  24. The method of operation of the CDMA system according to claim 23, wherein said adjusted repetition rate of signal elements of a reverse communication channel is equal to said base repetition rate of signal elements.  25. The method of operation of the CDMA system according to claim 23, wherein said maximum repetition rate of signal elements of a reverse communication channel is equal to said base repetition rate of signal elements.  26. The method of operation of the CDMA system according to claim 23, wherein said basic signal element repetition rate is equal to said corrected signal repetition rate of the forward communication channel signal and said repetition rate of the signal elements of the reverse communication channel.  27. The method of operation of the CDMA system according to claim 23, wherein said basic signal element repetition rate is equal to said maximum signal element repetition frequency of the forward communication channel and said maximum signal element repetition rate of the reverse communication channel.

Images