UA79237C2 - Communication techniques, communication system (variants), data transmission device (variants), data receiving device (variants) - Google Patents

Abstract

Systems and techniques for communications wherein a data packet is transmitted over at least one time slot from a transmission site, a value is computed from an initial value and information, the initial value being is function of the number of time slots of the data packet transmission, the value and the information is transmitted from the transmission side, the transmitted value and the intonnaliun is received a receiving sue, the value from the received information is recalculated, and the number of time slots of the data packet transmission is determined from the calculated and recalculated value. It is emphasized that this abstract is provided to comply with the rules requiring an abstract which will allow a searcher or other reader to quickly ascertain the subject manner of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or the meaning of the claims.

Description

Description of the invention

The invention generally relates to communication systems, in particular, to systems and methods of generating control information 2 for packet data transport.

Modern communication systems provide access to a common communication environment for many users. Numerous parallel access systems are known, for example, with time division (TOMA), by frequencies (ROMA), with spatial division, with code division (SOMA), etc. Concurrent access provides access to a shared communication environment for many users. The methods of assigning 70 channels depend on the type of parallel access. For example, in EOMA systems, the entire frequency spectrum is divided into a certain number of smaller subbands, and each user receives his own subband for accessing the communication environment. In TOMA systems, each user receives the entire spectrum during a time slot that is periodically repeated. In SOMA systems, each user receives the entire spectrum at all times, but separates his transmissions using a unique code. 12 Modulation and parallel access in SOMA systems is based on spectrum expansion. In such systems, multiple signals use a common frequency spectrum. This is achieved by transmitting each signal with a separate code that modulates the carrier and, therefore, extends the spectrum of the bypass signal. Transmitted signals are separated in the receiver by a demodulator, which uses a suitable code to narrow the spectrum of the desired signal. Unwanted signals whose codes are mismatched are not narrowed in the frequency band and are perceived as noise.

The use of SOMA for communication with parallel access generally increases user capacity compared to traditional TOMA and ROMA systems. As a result, more users can access the network, that is, communicate with each other through one or more base stations. In SOMA systems, channel assignment is based on orthogonal sequences known as Walsh codes. Depending on specific applications, any number of Walsh code channels may be required to support different control channels, such as the pilot channel and other shared channels. These channels require (3) consumption of system resources and therefore reduce user capacity, reducing the available resources needed to process traffic. Due to the very significant spread of wireless communication in recent years, there is a need for ways to build more efficient and reliable channels controls that would reduce computational complexity and maximize user capacity by providing more system resources for traffic.

One of the objects of the invention is a method of communication, which includes the transmission of a data packet during at least one "(there is a time slot from the place of transmission, the calculation of some value from the initial value and information, and this initial value is a function of the number of time slots for the transmission of the data packet , transmission of values and information from the place of transmission, reception of the transmitted values and information at the place of reception, recalculation of the value using the received information and determination of the number of time slots for the transmission of the data packet from the calculated and recalculated values.

Another object of the invention is a communication system including a base station (BS) having a channel element configured to generate a data packet spanning at least one time slot and to calculate an initial value and information, and this initial value is a function of the number of time slots of a data packet, a transmitter with a configuration that allows transmitting a data packet, values and information, C 50 a subscriber station having a receiver, the configuration of which allows receiving values and information from the BS, and c a processor, the configuration of which allows recalculate the value from the received information and determine the amount

From" the time slots of the data package from the calculated and recalculated values.

Another object of the invention is a transmission device that includes a channel element, the configuration of which allows the generation of a data packet spanning at least one time slot and the calculation of values and information, the initial value being a function of the number of time slots of the data packet, and 7 transmitter , which has a configuration that allows the transmission of data packets, values and information. (Te) Another object of the invention is a receiving device, which includes a receiver, the configuration of which allows receiving a data packet extending over at least one time slot, and a value and information, and the initial value is a function of the number of time slots of the data packet transmission, and the processor, the configuration of which allows to recalculate the values from the received information and determine the number of time slots of the data packet from the calculated and recalculated values. tm The object of the invention is also a computer-readable medium that embodies a program or instructions executed by a computer program and implements a method of communication, which includes generating a data packet extending at least one time slot, calculating some a value of 29 initial value and information, and this initial value is a function of the number of transmission time slots

HF) of the data packet, and the formatting of the data packet, values and information for transmission through the communication medium. o Another object of the invention is a communication system including a BS, which has a means of generating a data packet extending over at least one time slot, a means of calculating a value from an initial value and bo information, and this initial value is a function of the number of time slots transmission of a data packet, a means of transmitting a data packet, value and information, and a subscriber station, which has a means of receiving the value and information from the BS, a means of recalculating the value from the received information and a means of determining the number of time slots of the data packet using the calculated and recalculated values.

Another object of the invention is a transmission device, which includes a means of generating a data packet that spans at least one time slot, a means of calculating a value from an initial value and information, and this initial value is a function of the number of time slots of a data packet transmission, and a means formatting of the data package, values and information for transmission through the communication medium.

The object of the invention is also a receiving device, which includes a means of receiving a data packet transmitted during at least one time slot, a value and information, and this value is calculated from an initial value and information, and the initial value is a function of the number of time slots of data packet transmission, means recalculation of the value using the received information and a means of determining the number of time slots for transmitting a data packet from the calculated and recalculated values. 70 Other aspects of the invention are discussed in the following detailed illustrative description of typical embodiments of the invention.

It is clear that the invention may have other embodiments and modifications within the scope of the invention.

Next, the invention is illustrated by examples with reference to the drawings, in which: Fig. 1 is a functional block diagram of a typical communication system with SOMA, Fig. 2 is a functional block diagram of the main subsystems of a typical communication system with

SOMA fig. 1, fig. 3 - a functional block diagram of a typical channel element, the configuration of which allows the generation of information subpackets of a single-slot format, fig. 4 - a functional block diagram of a typical channel element, the configuration of which allows the generation of information subpackets of a two-slot format, and fig. 5 is a functional block diagram of a typical channel element, the configuration of which allows generating information subpackets in a four-slot format.

The following description illustrates typical embodiments of the invention, which are not the only possible embodiments of the invention.

The term "typical" herein means "exemplary, exemplary, or illustrative" and does not imply superiority over other embodiments. The description of individual details should contribute to a better understanding of the invention. It is clear, however, that the invention may be practiced without these specific details. In some cases, well-known structures and devices are shown as block diagrams to avoid unnecessary complication of the description.

In a typical embodiment of the communication system, data packets may be transmitted during one or more i) time slots. Each data packet is accompanied by an information sub-packet that includes the information required to decode the corresponding data packet and a value calculated from the initial value using this information. The value entered in the transmission can be used to determine the number of time slots used to transmit the corresponding data packet.

Various aspects of the use of these control channels are considered for communication systems with SOMA that support me) circuit-switched voice transmissions and high-speed data transmission. It is clear that these methods of using control channels can be applied in other switching environments. Therefore, references to SOMA systems are merely illustrative of an invention that actually has much broader applications. b"

Fig. 1 contains a simplified functional block diagram of a typical communication system with SOMA, which supports M circuit-switched voice transmissions and high-speed transmission of packet data. The controller 102 BOS (KBS) can perform the functions of the interface between the network 104 and all BS of a certain geographical region. This region is divided into subregions called cells or sectors. BS is assigned to serve all subscriber stations of the subregion. For simplicity, only one BS 106 is shown. Subscriber station 108 may have access to "

Network 104 or have communication with other subscriber stations (not shown) through one or more BS under the control of CBS 102. . Figure 2 contains a typical functional block diagram illustrating the basic subsystems of the communication system of Figure 1. KBES a 102 contains many selector elements (only one such element 202 is shown). One selector element controls transmissions between one or more BSs and one subscriber station 108. When communication is initiated, the communication session control processor 204 establishes a connection between the selector element 202 and the BS 106. After this, the BS 106 assigns an identifier to the Intermediate Controller Access (MAC) to identify connections of the subscriber station 108 through this connection. The designated MAC identifier can be transmitted from the BS 106 and to the subscriber station 108 in the process of exchanging signaling messages during the establishment of a communication session. The selector element 102 can be configured to receive circuit-switched 5p voice and data from the network 104. The selector element 202 sends this voice and data to each BS that has a connection with a given subscriber station 108. BS 106 generates transmission of a direct channel, which includes packet data of a direct "M channel for high-speed data transmission from BS 106 to one or more subscriber stations 108. A transmission channel from BS 106 to subscriber station 108 is called direct. A direct channel of packet data can consist of any number of Walsh code subchannels depending on the requirements of users of circuit-switched bv Gopos and data.

F) BS 108 can have a data queue 206 that buffers data from the selector element 202 before transmission to the subscriber station 108. Data from the data queue 206 can be sent to the channel element 208, which groups this data into a set of data packets. Depending on the number of data packets required for efficient data transport from selector element 202, any number of Walsh code subchannels may be used. Channel element 208 encodes the data packets using an iterative process, such as turbo coding, scrambles the encoded symbols using a long pseudorandom noise (PSN) sequence, and interleaves the scrambled symbols. Some or all of the interleaved symbols may be selected to form data subpackets for initial or retransmission in the forward channel. Further, the symbols of the b5 data subpackets may be modulated by the modulator 208 using quadrature-phase-shift manipulation (QPSK), 8-P5K, 16-OAM (quadrature-amplitude modulation), or other modulation known to those skilled in the art.

demultiplexed into phase (I) and quadrature (0) components and covered with a certain Walsh code. The data subpackets for each Walsh code can then be combined by channel element 208 and quadrature expanded using a short PS code. Short PS codes form the second level of coding, which is used to isolate one subregion from another. This solution allows Walsh codes to be reused in each subregion. The expanded Walsh subchannels are then sent to the transmitter 210 for filtering, frequency upscaling, and amplification prior to transmission in the direct channel from the BS 106 to the subscriber station 108 by the antenna 212 .

The control and scheduling functions are performed by the channel scheduler 214, which receives from the data queue 206 a queue size that indicates the amount of data to be transmitted to the subscriber station 108, and plans the size of the data subpackets and the data rate for the forward channel to maximize throughput. and minimize transmission delays based on the quality of the communication channel between BS 106 and subscriber station 108. The size of a packet or sub-packet of data is determined by the number of bits in them. Depending on the planned data packet size and transmission rate, data sub-packets may be transmitted in one or more slots.

In one typical embodiment of the SOMA system, data subpackets may be transmitted in one, two, four, or eight 1.25-millisecond time slots.

The channel scheduler 214 may also plan the modulation format of the data subpackets based on the quality of the communication channel between the BS 108 and the subscriber station 108. For example, in a relatively distortion-free environment with low or zero interference, the channel scheduler 214 may plan a high

Data rate for each subpacket in one time slot with 16-OAM modulation format. In case of poor channel conditions, the channel scheduler 214 may schedule the transmission of each low-rate subpacket in eight time slots with the ORBZK modulation format. A specialist can determine the optimal combination of transmission speed and modulation format to maximize system throughput.

Direct channel transmissions generated in BS 106 may also include one or more direct channel channels in the Data Packet Control. Conventional multi-slot high-speed data transmission systems sometimes use two such channels: primary and secondary direct packet control channels. Secondary i) direct data packet control channel carries information sub-packets that can be used by the subscriber station to receive or decode corresponding data sub-packets in the direct data packet control channel.

Similarly, the information subpackets transported by the secondary packet data control channel can sometimes be transmitted in one or more time slots to optimize communication with different subscriber stations having different channel conditions. In one typical embodiment of the SOMA system, the information subpackets (me) may be transmitted through the secondary direct packet data control channel in one, two, or four s 1.25 millisecond time slots depending on the number of time slots occupied by the corresponding data subpackets. For example, the information sub-packets may be transmitted in one slot for a single-slot data Mez sub-packet, in two slots for a two-slot data sub-packet, and in 4 slots for a four-slot data sub-packet. uh-

Different methods can be used to distinguish between four-slot and eight-slot subpacket formats. One solution may be to use different interleavers to rearrange the sequence of symbols in the BS depending on the four-slot or eight-slot transmission of the data subpacket. The number of time slots for an information sub-packet in the secondary direct packet data control channel can be determined from the information carried by the primary direct packet data control channel. in c In at least one embodiment of the communication system with SOMA, where multi-slot transmissions are used, the primary and secondary packet data control channels can be combined into one packet control channel;" data In this embodiment, the number of time slots for the information sub-packet carried in the direct packet data control channel can be determined from the information of this sub-packet in various ways.

For example, an information subpacket carried in a direct packet data control channel may have an added value for checking the code by cyclic redundancy check (CRC), which is calculated according to a known algorithm from the bit sequence that forms this information subpacket. The algorithm is primarily a process of division by i, in which the entire sequence of bits of an information subpacket is treated as a single binary number that is divided by a predetermined constant. The results of the division are discarded, and the remainders are stored as the KCN value.

This algorithm can be implemented programmatically or schematically. A shift register in combination with one or more keys is used for schematic implementation. The shift register accepts the information subpacket bit by bit. "M The content of the shift register after the completion of this process is the remainder of the division or the value of KCN. This method is well known.

In the subscriber station, the CCN check is performed for information subpackets addressed to the subscriber station using the MAC identifier. In particular, the KCN value can be recalculated for one or more time slots, recalculated values

Ф) are compared with the transmitted values of KCN added to the transmission of the direct channel. The length ka of the information sub-packet, i.e. the number of time slots it occupies, can then be determined from the recalculated value of the KCN, which coincides with the KCN transmitted in the forward channel. For example, if the value in the CTC calculated by the subscriber station for two time slots coincides with the CTC transmitted in the direct channel, the length of the information subpacket will be 2 time slots. If no CTC value calculated by the subscriber station matches the CTC transmitted in the direct channel, the subscriber station concludes that the corresponding information subpacket is intended for another subscriber station.

After determining the number of time slots occupied by the information subpacket, this number can be 65 used to decode that subpacket. If the subscriber station can successfully decode a data packet including the current data subpacket and any previously received subpackets of that data packet, it sends to

BS confirmation response (ASC) Otherwise, the subscriber station sends a negative confirmation message (ASC) by which it requests additional data subpackets. A data packet is considered to be successfully decoded if the values of the KCN match.

A sub-packet protected by CCN can provide increased system throughput by reducing the probability of false error messages in the direct packet control channel, i.e. the probability that a subscriber station will try to decode sub-packets intended for another subscriber station.

The KCN value can also be used to distinguish between four-slot and eight-slot subpacket formats.

This can be achieved by giving the initial CCC one or two different values depending on the format of the 7/0 data subpacket. The initial value of KCN is the content of the shift register before the information subpacket is shifted through it. In conventional SOMA systems that use error detection via CTC, the CTC value is calculated by a procedure that assigns only one value to the bits of the initial CTC. This procedure is convenient to use to identify data subpackets having one-, two-, or four-slot formats, although any initial value of the KCN can be used for this purpose. For eight-slot data packets, the /5 CTC value can be calculated by setting only zero initial values to the CTC bits, or other values that will distinguish eight-slot transmissions from four-slot transmissions. Such a solution may be more attractive than using two different interleavers to distinguish four-slot and eight-slot formats of data subpackets, as it simplifies calculations both in the BS and in the subscriber station.

Channel element 208 can be used to generate information for a direct control channel of 20 packet data. In particular, the channel element generates the payload by packing b6-bit identifiers

A MAC identifying the destination subscriber station, a 2-bit packet identifier that identifies the data subpacket, a 2-bit IF packet identifier that identifies the data packet from which the data subpacket was received, and

A 3-bit length field that indicates the size of the data subpacket.

The channel element 208 can be implemented schematically or programmatically, or in combination, and can be implemented with a general-purpose processor, a digital signal processor (DSP), a specialized application integrated circuit (API), a programmable set of field keys, or other programmable logic device, discrete key or transistor logic, discrete circuit elements, or any combination thereof designed to perform one or more of the functions described herein. In one of the embodiments of the channel element 208, its functions can be performed by a general-purpose processor, for example, a microprocessor or a specialized processor, for example, a programmable O5R with a built-in communication layer of software for implementing the functions of the channel element. In this embodiment, this communication layer can be used to initiate various encoders, modulators, and auxiliary functions during multi-slot transmissions.

Fig.3 contains a functional block diagram of the configuration of a channel element, which allows generating a typical Me direct channel of packet data control for single-slot transmission. In this configuration, a 13-bit payload is supplied to the 202 KCN M generator. The KCN generator can be used to calculate the value

KCN for all or part of the load. By calculating the value of KCN for part of the payload, the calculation can be simplified. The KCN value can contain any number of bits depending on the system parameters. In the typical embodiment described, the KCN generator 202 adds 8 bits to the payload. « A 21-bit payload protected by the CCN is sent to the tail generator of the coder, which generates from c a sequence of bits that is added to the end of the payload. The sequence of bits forming the tail is . provides for the decoder of the subscriber station a sequence ending with a known state, and thus provides accurate decoding. The tail generator can generate an 8-bit tail, although the length of the tail can be arbitrary. The 29-bit payload, protected by the CCS, with the encoder tail is fed to the convolutional encoder 306, -I, which provides the subscriber station with the ability for preliminary error correction and can provide any coding rate and length limitation depending on the parameters and general system limitations. In a typical embodiment (Fig. 3), convolutional coding is performed at a rate of 1/2 with a length limit of 9. As a result, a 29-bit sequence entering the convolutional encoder is encoded into a 58-bit sequence. Collapsing

Coding is well known and one of skill in the art can determine the proper rate and length limits to optimize performance. "M Depiler 308 is used to depilate 10 symbols from the 58-bit sequence coming from convolutional encoder 306. The final 48-character sequence gives a transmission rate of 38.4 kbit/s for a single-slot transmission of 1.25 ms duration. The number of symbols that extracted from the original sequence of two bisymbols, can vary according to various system parameters to obtain the optimal symbol rate based on the encoding speed of the convolutional encoder and the duration of the time slot of the communication system.

F) Different methods of minimizing the effect of serial errors on the ability of the decoder of the subscriber station to decode the sequence of symbols can be applied to 48-character sequences. For example, a 48-character sequence from element 308 may be sent to block interleaver 310, which reorders into a sequence of characters.

The sequence of symbols from the block interleaver 310 can be sent to a modulator 314 capable of supporting various modulation schemes, for example, ORBC, 8-RBC, 16-OAM, etc. In the described embodiment, the modulator 314 ORBK is used. The modulated symbols from the modulator 314 can then be divided into components I and C) and covered with a certain Walsh code in the multiplier 316 before combining into the direct channel b5 packet data and other Walsh subchannels. The Walsh subchannels can then be quadrature expanded with short PS codes and sent to the transmitter 210 for filtering, frequency enhancement and amplification before transmission in the direct channel from BS 106 to subscriber station 108 (Fig. 2).

Fig.4 contains a functional block diagram of the configuration of a channel element, which allows generating a typical direct channel of control of packet data for two-slot transmission. As with the single-slot format, the 13-bit payload may be appended with an 8-bit CCN value generated by the generator 402

KCN, and the 8-bit coder tail generated by the coder tail generator 304. The resulting 29-bit sequence can be sent to a convolutional encoder 406, which, due to the two-slot format, has a speed of 1/4 with a length limit of 9 and produces a 116-character sequence. Depiler 404 is used to depilate 20 symbols from the 116-bit sequence coming from convolutional encoder 406. The final 70 48-character sequence yields a transmission rate of 38.4 kbit/s for a two-slot transmission of 1.25 ms.

The remaining functions of the channel element are similar to those described for Fig.3. The 9b-character sequence is then interleaved, divided into components I and C) and covered with a specific Walsh code before combining into a direct packet data channel and other Walsh subchannels. The Walsh subchannels can then be quadrature expanded with short PS codes and sent to the transmitter 210 for filtering, frequency upscaling and amplification before transmission in the direct channel from BS 106 to subscriber station 108 (FIG. 2).

Fig.5 contains a functional block diagram of the configuration of the channel element, which allows generating a typical direct channel of packet data control for four-slot transmission. As in the previous cases, an 8-bit CCN value generated by the CCN generator 302 and an 8-bit encoder tail generated by the encoder tail generator 304 may be added to the 13-bit payload. The resulting 29-bit sequence can be sent to a convolutional encoder 402, which, due to the two-slot format, has a speed of 1/4 with a length limit of 9 and produces a 116-character sequence. Punching out 20 characters gives a 96-character sequence.

The main difference between two-slot and four-slot transmission formats is the presence of sequence repeater 502 after punching element 404 to construct the four-slot format. Repeater 502 can be used to repeat the 9b-character sequence twice and thus produce a 192-character sequence to match the four-slot transmission format. In this embodiment, the sequence repeater 502 is located at the output of the punching element 308; however, the repeater 502 may be installed before or after the puncturing element 404. The sequence repeater 502 may be configured to repeat the sequence of symbols as many times as the system characteristics require. For example, a convolutional encoder can have a rate of 1/2 and generate a 58-character izo sequence. From this sequence, the punching element punches out 10 symbols and the resulting 48-character sequence is repeated by repeater 502 4 times according to the four-slot format of transmission. The specialist can easily choose the number of repetitions and the speed of the convolutional encoder to optimize the operation of the system in the case of one-, two-, four-slot formats and formats of other multiplicity.

The remaining functions of the channel element are similar to those described for Fig.4. The 192-character sequence is then interleaved, divided into components | and 2) and is covered with a certain Walsh code before combining into the direct packet data channel and other Walsh subchannels. The Walsh sub-channels can then be quadrature expanded with short PS codes and sent to the transmitter for filtering, frequency enhancement and amplification before transmission in the direct channel from BS 106 to subscriber station 108 (Fig.2).

Transmissions from the BS 106 (Fig. 2) are received by the antenna 214 of the subscriber station 108. The received signal from the antenna 214 reaches the receiver 216, which filters and amplifies the signal, lowers its frequency to the modulation frequency and quadrature demodulates it with c. Next, samples are taken from the signal and stored in memory 218, which must have a volume sufficient to store such a number of samples that covers the maximum allowable number of time slots for subpacket transmission in the direct channel.

In a typical SOMA system, samples are released from memory 218 to processor 220 in a one-, two-, or four-slot format. The processor 220 performs several functions, illustrated in Fig. 2 by the demodulator 222, -I encoder 224, the KCN generator 226 and the comparator 228. These functions can be implemented schematically or performed programmatically by the processor or combined. The processor can be implemented as a specialized and, or as a general-purpose processor, as OBR, ABIS, ERSA or as another programmable logic device, in the form of discrete key or transistor logic, discrete circuit components or as a combination thereof, designed to perform one or more of the specified above functions. It is clear that a separate processor can be provided to perform each of these o functions, or several functions can be distributed among any "M number of processors.

In one of the typical implementations of the SOMA system, the memory 218 first releases one time slot of samples for the modulator 222, which quadrature demodulates them with short PS codes and collapses them into symbols using Walsh codes. The symbol sequence for the forward control channel of the data packet can then be demodulated using ORBC, 8-RZK, 16-OAM, or another modulation scheme used in the BS (F. 106. The demodulated symbol sequence can be sent to the decoder 224, which performs functions that are the reverse of those performed in BS, in particular, reverse interleaving and decoding.

If the decoded bit sequence contains the MAC identifier for the subscriber station, this sequence may be sent to the CTC generator 226, which calculates the CTC value according to a procedure that gives the bits of the initial CTC only single values. The locally generated value of KCN in the comparator 228 is compared with the decoded value of KCN included in the transmission of the direct channel. If these values match, the length of the information subpacket is determined to be equal to one time slot, and the payload can be used by the processor 220 to decode the corresponding data subpacket. 65 If the locally generated CTC value differs from the decoded CTC value included in the direct channel transmission, it means that the information subpacket has been distorted or has a length of more than one time slot. In this case, the processor 220 releases two time slots of the samples from the memory 218 for demodulation, decoding and verification of the CCS. Next, the processor 220 calculates a new CTC value with the single bits of the original CTC and compares the locally generated CTC value with the decoded CTC value included in the forward channel transmission. If the comparison is successful, the length of the information subpacket is determined to be equal to two time slots. In this case, the payload can be used to decode the corresponding data subpacket.

If the locally generated KCN value differs from the decoded KCN value included in the direct channel transmission, the processor 220 releases four sample time slots from the memory 218 for demodulation, /o decoding and verification of the KCN. Next, the processor 220 calculates the new value of the KCN with the single bits of the initial one

The CTC compares the locally generated CTC value with the decoded CTC value included in the forward channel transmission. If the comparison is successful, the length of the information subpacket is determined to be equal to four time slots. In this case, the payload can be used to decode the corresponding data subpacket.

If the locally generated CTC value does not match the decoded CTC value included in the forward channel transmission, the processor 220 determines whether the decoded CTC value is suitable for the CTC value calculated in the BS with initial zero values of all bits. This can be done, for example, by recalculating the locally generated value of the KCN with initial zero values of all bits. Another variant provides for the execution of a bitwise addition function by that 2 between the locally generated KCN value (with initial single values of all bits) and a predetermined sequence of bits. This sequence of bits can be calculated through the addition of two possible locally generated initial values

CTC (in this case all zero and all one bits) and calculating the CTC value that can result from inputting a sequence of zero bits, the number of which is equal to the number of payload bits, into a similar CTC generator with the initial CTC value set equal to the result of this addition for that 2. sch

The resulting KCN value will be that which would be obtained by calculating the KCN value with the initial and zero values of all KCN bits. I Regardless of the selection of the solution, the value will be recalculated i)

The CTC can be compared to the decoded CTC value included in the forward channel transmission. If these values match, the length of the information subpacket is determined to be equal to eight time slots. In this case, the payload can be used to decode the corresponding data subpacket. If these values differ, the subscriber station decides that the corresponding data subpacket is intended for another subscriber station. me)

Logical blocks, modules, schemes and algorithms, which relate to the embodiments of the invention presented here, can be implemented schematically, programmatically or in combination. To illustrate the interchangeability of circuit and software solutions, various components, blocks, modules, circuits and algorithms were described through the impulse characteristic of the function. Me

C5 Software or schematic implementation depends on the specific application, construction and limitations of the system. These M functions can be implemented in different ways for different applications, but such implementations cannot be considered as outside the scope of the invention. A general-purpose processor can be a microprocessor or a conventional processor, a controller, a microcontroller, or a finite state machine.

The processor can also be a combination of computing devices, for example, a combination of O5R and a microprocessor, a set of microprocessors, one or more microprocessors in combination with an OP core with c, or any similar configuration.

The operations of the algorithm of the method, described in the embodiments, can be implemented schematically, programmatically or;" combined Program modules can be stored in KAM, flash memory KOM, PZP, NZP, registers, on a hard disk, on a removable disk, SO-KOM or in another known storage medium. In a typical embodiment, the processor and memory are interconnected in such a way that the processor can read information from the memory and write it to the memory. In another embodiment, the processor and memory can be integrated and, as an option, reside in the ABIS, which can be located in the access terminal. In another variant, the processor and memory can be made as discrete components of the access terminal. The following description of preferred embodiments enables a person skilled in the art to practice the invention. Various modifications of these embodiments and the principles of the invention will make it possible to build other embodiments without additional invention. The invention is not limited to these embodiments and its scope is determined by its principles and new features. what

Claims (30)

The formula of the invention, , , , , 1. A method of communication containing stages in which: information is received for transmission, (F. determine the number of time intervals for the transmission of a data packet, calculate the error control value from the GI of the initial value selected from the set of initial values, and the information of the initial value and the error control value, which are a function of the number of time intervals, transmit the calculated error control value of the mentioned information in the data packet during the mentioned number of time intervals, accept the calculated error control value of the said information, recalculate the error control value from the received information and at least one initial value selected from the set of initial values, determine the number of time intervals using the calculated error control value and where Recalculated error control value. 2. The method according to claim 1, which is characterized by the fact that the calculated error control value and the recalculated error control value contain cyclic redundant code control values. C. The method according to claim 2, which is characterized in that the calculated value of the cyclic redundant code control contains a first initial value if the data packet is transmitted during the first number of time intervals, and a second initial value if the data packet is transmitted during the second number of time intervals. 4. The method according to item C, which is characterized by the fact that the data packet is transmitted during the first number of time intervals, and the step in which the number of time intervals of the data packet transmission is determined includes a step in which the calculated and recalculated control values are compared by the cyclic redundant code . 5. The method according to point 3, which differs in that the data packet is transmitted during the second number of time intervals, and the stage at which the number of time intervals for transmitting the data packet is determined includes stages at which summation is performed modulo 2 of the recalculated value cyclic redundant code control with a predetermined value, and compare the result with the calculated cyclic redundant code control value. 6. The method according to point 3, which is characterized by the fact that the calculated value of the cyclic redundant code control and the mentioned information are transmitted during the first number of time intervals. 7. The method according to claim 6, which differs in that the first number of time intervals contains four time intervals, and the second number of time intervals contains eight time intervals, and each time interval is equal to 1.25 milliseconds. 8. A communication system comprising: a base station having a channel element configured to generate a data packet that continues for at least one time interval and to calculate an error control value from an initial value and information, wherein the initial value is a function of the number of time slots of the data packet, and a transmitter configured to transmit a data packet containing the calculated error control value and said information and a subscriber station having a receiver configured to receive a data packet containing c the calculated error control value and said information, from the base station, and a processor configured to recalculate the error control value and the received information and determine the number of i) time intervals of the data packet from the calculated and recalculated error control value. 9. The communication system according to claim 8, which is characterized in that the calculated error control value and the recalculated error control value contain cyclic redundant code control values. cha zo 10. The communication system according to claim 9, characterized in that the channel element is also configured to set the calculated control value of the cyclic redundant code to a first initial value, o if the data packet continues for a first number of time intervals, and to a second initial value value, if the c data packet continues during the second number of time intervals. 11. The communication system according to claim 10, characterized in that the data packet continues for a first number of Me Z time intervals, and the processor is also configured to determine the number of time intervals of the M data packet by comparing the calculated and recalculated control values cyclic redundant code. 12. The communication system according to claim 10, characterized in that the data packet continues for a second number of time intervals, and the processor is also configured to determine the number of time intervals of the data packet by summation modulo 2 of the recalculated cyclic control value excessive 2-2 s code with a predetermined value and comparison of the result with the calculated control value . cyclic redundant code. and 13. The communication system according to claim 10, which is characterized in that the calculated control value of the cyclic redundant code and said information continues during the first number of time intervals. 14. The communication system of claim 13, wherein the first number of time slots comprises four -I time slots, and the second number of time slots comprises eight time slots, each time slot being 1.25 milliseconds. ise) 15. A data transmission device comprising: a GI channel element configured to generate a data packet lasting at least one time slot and to calculate an error control value from an initial value and information, wherein the initial value is a function of the number of time slots of the data packet, and set the initial AND value for the calculated cyclic redundant code control value to the first initial value if the data packet continues for the first number of time intervals, and to the second initial value if the data packet continues for the second number of time intervals, 5B transmitter configured so as to transmit a data packet, an error control value and said information, wherein the calculated error control value includes a cyclic F) redundant code control value, wherein the calculated cyclic redundant code control value and said information co are continued for a first number of time slots, and first or the time slot layer contains four time slots and the second number of time slots contains eight time slots, each time slot being equal to 1.25 milliseconds. 16. A data receiving device, which includes: a receiver configured to receive a data packet transmitted during at least one time interval, and an error control value and information, and the error control value is calculated from the initial value and information, and the initial value is as a function of the number of time intervals 65 of data packet transmission, the processor is configured to recalculate the error control value from the received information and determine the number of data packet transmission time intervals from the calculated and recalculated error control values. 17. The receiving device according to claim 16, which is characterized in that the calculated and recalculated values of the Error Control contain the values of the cyclic redundant code control. 18. The receiving device according to claim 17, characterized in that the processor is also configured to determine the number of time intervals for transmitting a data packet by comparing the calculated and recalculated values of the cyclic redundant code control. 19. The receiving device according to claim 18, characterized in that the processor is also configured to determine the number of time intervals of the data packet by summing modulo 2 the recalculated control value by the cyclic redundant code with a predetermined value and comparing the result with by the calculated control value of the cyclic redundant code. 20. A communication system that includes: a base station for generating a data packet that continues for at least one /5 Time interval, a means for calculating an error control value from an initial value and information, and the initial value is a function of the number of time intervals of the package data, and a means for transmitting a data packet, a calculated error control value and information, a subscriber station for receiving a calculated error control value and information, a means for recalculating the error control value from the received information, a means for determining the number of time intervals of a data packet from the calculated and recalculated error control values. 21. The communication system according to claim 20, characterized in that the base station also includes means for setting the calculated control value of the cyclic redundant code to a first initial value if the data packet c ob continues for a first number of time intervals, and to a second initial value value if the data packet o continues for the second number of time intervals. 22. A communication system according to claim 21, characterized in that the data packet continues for a first number of time intervals, and in which the means for determining the number of time intervals also includes means for comparing the calculated and recalculated control values by the cyclic redundant code. food 23. The communication system according to claim 21, characterized in that the data packet continues for a second number of time intervals, and in which the means for determining the number of time intervals also includes means for me) summing modulo 2 of the recalculated control value by cyclic excess code with a previously determined value and comparison of the result with the calculated control value by the cyclic redundant code. 24. The communication system according to claim 21, which is characterized by the fact that the calculated amount of control by the cyclic excessive Me Zv Code and the information continues during the first number of time intervals. M 25. The communication system of claim 24, wherein the first number of time slots comprises four time slots and the second number of time slots comprises eight time slots, each time slot being 1.25 milliseconds. 26. A data transmission device that contains: "means designed to generate a data packet that continues for at least one s time interval, means designed to calculate an error control value from an initial value and information, with" the initial value being as a function of the number of time intervals of the data packet, the means for formatting the data packet, the calculated error control value and information for transmission via the communication medium, -And the calculated error control value contains the calculated cyclic redundant code control value, and and, while the calculated cyclic redundancy check value contains a bit sequence, GI means, which sets the initial value for the calculated cyclic redundancy check value s 50 to a first value if the data packet continues for a first number of time slots and to a second value if the data packet continues for of the second number of time intervals, and at the same time the calculated value control by a cyclic redundant code and the information continues for a first number of time slots, the first number of time slots includes four time slots, and the second number of time slots includes eight two time slots, and each time slot is equal to 1.25 milliseconds. 27. A data receiving device that contains: Ф) means intended for receiving a data packet transmitted during at least one time interval, and error control values and information, and the error control value is calculated from the initial value and information, while the initial value is as a function of the number of data packet transmission time intervals, to a tool designed for recalculating the error control value from the received information, a tool for determining the number of data packet transmission time intervals from the calculated and recalculated error control values. 28. The receiving device according to claim 27, which is characterized in that the calculated error control value and the recalculated error control value contain cyclic redundant code control values. 65 29. The receiving device according to claim 28, characterized in that the means for determining the number of time intervals also includes means for comparing the calculated and recalculated check values by the cyclic redundant code. 30. The receiving device according to claim 28, which is characterized in that the means for determining the number of time intervals also includes a means for performing summation modulo 2 of the recalculated control value by the cyclic redundant code with a predetermined value and comparing the result with the calculated control value by the cyclic redundant by code s z (8) cha (ze) s (o) and - - with I.Y and? -I se) ime) o) 70 what ime) 60 b5