RU2232466C2 - Device and method for measuring propagation time delay in mobile narrow-band code-division multiple access communication system - Google Patents

Abstract

FIELD: radio communications.

SUBSTANCE: proposed device and method provide for measuring propagation time delay in mobile narrow-band code-division communication system. To this end user equipment enters in synchronism with station B by means of downlink pilot-channel signal transferred during cannel interval of downlink pilot channel and measures estimating value T1 of two-way delay at the same time comparing transmitted power of common physical channel signal during first channel interval with received power of common physical channel signal.

EFFECT: enlarged functional capabilities.

26 cl, 13 dwg

Description

BACKGROUND OF THE INVENTION

FIELD OF THE INVENTION

The present invention relates, in General, to a device and method for measuring propagation delay in a CDMA mobile communication system (code division multiple access) and, in particular, to a device and method for measuring propagation delay in a CDMA narrowband mobile communication system operating in time division duplex mode (UP-DVR).

State of the art

In general, CDMA mobile communication systems are divided into systems operating in full-duplex frequency division (DFD) mode, in which the receiving frequency and transmission frequency are separated, and operating in time-division duplex mode (DLC), in which downlink channels and uplink are separated by time. In particular, the DVR system provides for dividing the channel intervals forming the frame into intervals for the downlink channel and intervals for the uplink channel. Additionally, DVR systems are divided into the ШП-ДВР system (broadband, operating in full-duplex mode with a time division) and UP-DVR (narrow-band, operating in full-duplex mode with a time division). The ШП-ДВР system and the HDR system support a signal element repetition rate of 3.84 Element / s, while the UP-DVR system supports a signal element repetition rate of 1.28 Element / s.

Currently, the current work on the international standardization of promising mobile communication systems is being carried out in the areas of an asynchronous system, which is the UMTS (Universal Mobile Communication System) and a synchronous system, which is the cdma-2000 system. The technologies of the ШП-ДВР system and the UP-ДВР system for an asynchronous system are defined in 3GPP (Cooperation Project on the Development of a 3rd Generation Communication System).

Meanwhile, in the CDMA mobile communication system, when data is exchanged between the Node B and the software (user equipment) over the air, there is inevitably a delay in distribution. In mobile communication systems CDMA ШП-ДВР and ДРЧ, the propagation delay is measured as the time it takes for a signal transmitted by software via a random access channel (RACH) to reach Node B.

Figure 1 shows an example of a two-way delay occurring in a mobile communication system CD-DVR mdcr. According to FIG. 1, UTRAN (UMTS Terrestrial Radio Access Network), the term used in an asynchronous CDMA mobile communication system includes a Node B serving a radio network controller (CSNC) for managing a plurality of Nodes B, and a core network (BS).

We describe a method for measuring two-way delay with reference to FIG. The Node B included in the UTRAN can measure the bi-lateral delay value by calculating the difference between the reference arrival time A of the RACH signal and the actual arrival time B of the RACH signal. The software transmits on RACH at a specific time. The reference arrival time A is the expected arrival time of the RACH signal, determined by the Node B taking into account the expected propagation delay, and the actual time of arrival B is the time of the actual reception of the RACH signal on the Node B. The two-way delay value is the time period between the data transmission time by the Node B on the software and the time at which the Node B receives the response from the software to the transmitted data. Node B knows in advance the reference arrival time A. Thus, by measuring the actual arrival time B, Node B can calculate the value of the two-way delay. This means that Node B can calculate the desired value of the actual two-way delay by adding to the expected value of the two-way delay an offset (or error) between the reference arrival time A and the actual arrival time B. In addition, the actual value of the propagation delay from software to Node B, halving the calculated value of the two-way delay.

The propagation delay value measured by the Node B is transmitted to the OCRS serving the software via a frame protocol message. A frame protocol message is a message exchanged between Node B and OCRS. The Node B transmits the measured propagation delay value to the OCRS, adding it to the frame protocol message header.

In a CDMA CDMA mobile communication system, the propagation delay value measured by the Node B and then transmitted to the SSC is used when the SSC sets the transmit power needed to transmit data on the forward access channel (FACH). In addition, the propagation delay value can be used to provide a location service (PTO) that allows you to evaluate the current location of the software. Thus, the CSRC determines the optimal level of transmitted power for transmitting the FACH frame to the software by analyzing the propagation delay value of the signal received from the Node B, and transmits the found power level value to the Node B. The Node B then transmits via FACH to the software using the preferred level of transmitted power, the value of which was received from OCRS. The higher the propagation delay value measured by the Node B, the higher the transmit power level from which the Node B transmits the FACH frame.

According to the foregoing, the CDMA mobile communication systems CD-DVR and HDR use the RACH provided for transmission from the software to the Node B to measure the propagation delay. The software transmits the RACH signal during the channel interval of the Node B or at the initial moment of the frame. For this, the software must be synchronized with the Node B. The software is synchronized with the Node B using the primary common physical control channel (R-SSRSN), through which the Node B transmits.

However, in the CDMA UP-DVR system, since the software transmits the RACH signal, waiting for the moment of transmission of the uplink channel interval, the above-described method of measuring the propagation delay does not allow measuring the propagation delay value.

The reason why the CDMA UP-DVR mobile communication system cannot measure the propagation delay time will be described in detail below. In a mobile communication system UP-DVR mdcr, one frame is considered a “radio frame”, and the duration of the radio frame is 10 ms. The radio frame is divided into two subframes, each of which has a length of 5 ms and contains 7 channel slots.

FIG. 2 shows the structure of a subframe commonly used in a CDMA UP-DVR mobile communication system. According to figure 2, the subframe contains 7 normal channel intervals KI0-KI6, the channel interval of the pilot channel downlink (N-CRP) and the channel interval of the pilot channel uplink (B-CRP). In FIG. 2, the channel slots indicated by the arrows pointing downward are the channel slots of the downlink allocated for transmission from the Node B to the software, and the channel slots indicated by the arrows pointing upward are the channel slots of the uplink allocated for the transmission from the software to the Node B. N-PCI is the time period when the Node B transmits to the software the specified code sequence by means of the pilot signal of the downlink, which allows the software to synchronize with the Node B. In-CRP - is the time period when the UE transmits to the Node B a particular code sequence, for example for power control, by means of a pilot channel uplink signal. The boundary between the downlink channel interval and the uplink channel interval is indicated in FIG. 2 as a “switching moment”. Among the channel slots, the first channel slot KI0 is constantly used as the channel interval of the downlink, and the first channel slot KI0 is used to transmit the P-SSRC signal.

Now consider the reason why the mobile communication system UP-DVR mdcr supporting the structure of the radio frame shown in figure 2, can not accurately measure the propagation delay.

According to the foregoing, in the CD-UP CDMA mobile communication system, the separation between the uplink and the downlink is carried out by channel intervals. Therefore, the software must transmit the uplink signal so that the uplink signal does not interfere with the downlink signal at the Node B. This means that the software transmits the uplink signal so that the Node B can receive the uplink signal during the uplink channel interval shown in FIG. Therefore, in the CDMA UP-DVR mdcr mobile communication system, the software synchronization operation with the Node B is certainly required. The software is synchronized with the Node B using the channel interval of the downlink pilot channel (N-CRP) received from the Node B.

Having synchronized with the Node B, the software receives the signal of the primary common physical control channel (PFKU, R-SSRSN), transmitted by the Node B, and estimates the approximate distance to the Node B, measuring the losses on the R-SSRSN track by its attenuation. Having estimated the distance to the Node B, the software shifts the moment of transmission of the B-CRP signal so that the Node B can receive the B-CRP signal at the initial boundary moment of the B-CRP.

The reason that the Node B must receive the V-CRP signal from the software at the initial boundary moment is to prevent interference caused by the overlapping (overlapping) of the downlink signal and the uplink signal in the UP-DVR system, in which the separation between the downlink signal and the uplink signal is carried out according to the principle of time separation.

The Node B receives the B-CRP signal and determines whether the B-CRP signal was received exactly during its B-CRP. If there is a time difference, the Node B transmits to the software the correction value of the moment of transmission via the direct physical access channel (PFKD, FPACH). Having received the correction value of the transmission moment via FPACH, the software transmits a message on the RACH channel at the time of transmission, adjusted according to the received correction value of the transmission moment. This means that the software determines the transmission moment of the RACH message using the correction value of the transmission moment received by FPACH. Therefore, a RACH message may arrive at Node B at an optimal time.

However, the Node B cannot know how much the software has shifted the moment of transmission of the B-CRP signal so that the Node B can receive the B-CRP signal at the initial boundary moment of the B-CRP. Therefore, the Node B cannot measure the propagation delay of the B-CRP signal from the software and, therefore, cannot correctly control the transmitted power in accordance with the propagation delay.

SUMMARY OF THE INVENTION

The objective of the present invention is to provide a device and method for measuring the propagation delay between the Node B and the software in the mobile communication system UP-DVR mdcr.

Another objective of the present invention is to provide a device and method for measuring the propagation delay value by the Node B and transmitting the measured propagation delay value to the OCRS in the CDMA UP-DVR mobile communication system.

Another objective of the present invention is to provide a device and method for measuring in software the value of the propagation delay and transmitting the measured value of the propagation delay to the OCRS in the CDMA UP-DVR mobile communication system.

Another objective of the present invention is to provide a device and method for measuring the value of the propagation delay using RACH in a mobile communication system UP-DVR mdcr.

Another objective of the present invention is to provide a device and method for measuring the value of the propagation delay using a dedicated channel in a mobile communication system UP-DVR mdcr.

A first aspect of the present invention provides a method for measuring a propagation delay value for a frame transmitted from software to the Node B in the DVR mobile communication system in which the frame is divided into two subframes, each of which contains a plurality of channel slots and also comprises a channel interval of the downlink pilot channel the communication lines and the channel interval of the uplink pilot channel, which are both between the first channel interval and the second channel interval of the plurality of channel intervals, the system also contains a Node B transmitting a frame attached to a time axis, and software that, having received a frame from Node B, transmits a frame taking into account the propagation delay. The method comprises the steps of being in synchronism with the Node B using the downlink pilot channel signal transmitted during the channel interval of the downlink pilot channel, and determining the estimated value of the bilateral delay T1 by comparing the transmitted signal power of the physical common channel in the first channel interval with the received signal power of the physical common channel; transmitting the uplink pilot channel signal by using the estimated bi-lateral delay value T1 for the desired transmission moment of the uplink pilot channel signal; receiving a correction value T2 of a transmission moment by means of a direct physical access channel (FPACH) signal transmitted from Node B during one downlink channel interval from a plurality of channel intervals; and transmitting the physical random access channel (PRACH) message containing the estimated value T1 of the two-way delay at the time of transmission, determined based on the correction value T2 of the moment of transmission and the estimated value T1 of the two-way delay, which allows the Node B to receive the PRACH message at the initial moment of one channel interval uplink from a set of channel intervals.

A second aspect of the present invention provides a method for measuring a propagation delay value for a frame transmitted by the Node B to software in a DVR mobile communication system in which the frame is divided into two subframes, each of which contains a plurality of downlink channel slots, a plurality of uplink channel slots , the channel interval of the downlink pilot channel and the channel interval of the uplink pilot channel, and further comprising a Node B for transmitting a physical common signal channel during the first channel interval of the subframe, and software for calculating the estimated value T1 of the bilateral delay based on the path loss of the signal of the physical common channel and the transmission of the channel interval of the pilot channel of the uplink, taking into account the calculated value T1 of the bilateral delay. The method comprises the steps of determining a correction value T2 of a transmission moment based on an offset between the moment of arrival of the uplink pilot channel signal and the desired time of arrival of the uplink pilot channel signal over the channel interval of the uplink pilot signal; include the correction value T2 of the moment of transmission in the direct physical access channel signal (FPACH) and transmit the FPACH signal to the software within one channel interval of the downlink from the set of channel intervals of the downlink; receive a physical random access channel (PRACH) message with a bi-lateral delay estimated value T1, which software message sent at the time of transmission, determined based on the transmission moment adjustment value T2 and bi-lateral estimated value T1, over one channel interval of the uplink from uplink channel slots; and transmitting the estimated value T1 of the bilateral delay and the correction value T2 of the transmission moment included in the PRACH message to the radio network controller (RNC) to which the software belongs, together with the RACH signaling message, which allows the RNC to determine the two-way delay between the Node B and the ON.

According to a third aspect of the present invention, there is provided an apparatus for measuring a propagation delay value between frames between a software and a Node B in a DVR mobile communication system comprising a frame divided into two subframes, each of which contains a plurality of downlink channel slots, a set of uplink channel intervals lines of communication, the channel interval of the pilot channel of the downlink and the channel interval of the pilot channel of the uplink and further comprising a Node B for transferring transmitting the physical common channel signal during the first channel interval of the subframe, and software for calculating the estimated value of T1 bilateral delay based on the path loss of the signal of the physical common channel and transmitting the channel interval of the uplink pilot channel taking into account the calculated bilateral delay value T1. The software transmits the uplink pilot channel signal at the time of transmission determined using the bidirectional delay estimated value T1 at the desired moment of transmission of the uplink pilot channel signal and transmits a physical random access channel (PRACH) message with the estimated delay value T1, in transmission moment determined based on the correction value T2 of the transmission moment and the estimated value T1 of the two-way delay received by the direct physical channel signal pa (FPACH). The Node B determines the correction value T2 of the transmission moment based on the offset between the moment of arrival of the uplink pilot channel signal and the desired time of arrival of the uplink pilot channel signal, transmits a certain correction moment T2 of the transmission moment together with the FPACH signal during this downlink channel interval communication line and transmits the estimated value T1 of the two-way delay and the correction value T2 of the transmission moment included in the PRACH message received in the initial m The moment of this uplink channel interval to the radio network controller (RNC) together with the RACH signaling frame. The RNC receives the RACH signaling frame and determines the two-way delay between the software and the Node B based on the estimated two-way delay value T1 and the transmission timing correction value T2 included in the received RACH signaling frame.

Brief Description of the Drawings

The above and other objectives, features and advantages of the present invention are clarified in the following detailed description, given in combination with the accompanying drawings, where:

figure 1 - diagram of the two-way delay taking place in the mobile communication system ШП-ДДР mdcr;

figure 2 - diagram of the structure of a subframe used in a mobile communication system UP-DVR mdcr;

figure 3 - diagram of the propagation delay for the channel interval downlink in a mobile communication system UP-DVR mdcr;

4 is a diagram of the propagation delay for the channel interval of the uplink in the mobile communication system UP-DVR mdcr;

5 is a diagram of a method for transmitting on a direct physical access channel (FPACH) to compensate for propagation delay for an uplink channel interval in a CDMA UP-DVR mobile communication system;

FIG. 6 illustrates a frame format of a random access channel (RACH) through which transmission is made from Node B to a serving radio network controller (RNC) in a CDMA UP-DVR mobile communication system;

Fig.7 illustrates the propagation delay for the channel intervals of the pilot channel of the uplink communication (V-CRP) involved in the transmission of two software in a mobile communication system UP-DVR mdcr;

Fig. 8 illustrates a method for measuring an arrival time offset at a Node B in a CDMA UP-DVR mobile communication system;

Fig.9 illustrates the operation of the software when measuring the value of the propagation delay in the mobile communication system UP-DVR mdcr according to a variant implementation of the present invention;

10 illustrates the operation of a Node B in measuring a propagation delay value in a CDMA UP-DVR mobile communication system according to an embodiment of the present invention;

11A-11C illustrate various methods for transmitting a RACH signaling message according to an embodiment of the present invention.

Detailed Description of a Preferred Embodiment

A preferred embodiment of the present invention is described below with reference to the accompanying drawings. In the following description, well-known structures or structures are not described in detail, so as not to obscure the invention with irrelevant details.

Despite the lack of description of objects not directly related to the present invention, for a better understanding of the invention, references to objects accepted by 3GPP or submitted for consideration can be used. In addition, although a description of the present invention is made with reference to the UP-DVR system, the present invention is also applicable to any system that cannot measure two-way delay, for example, to the existing UP-DVR system.

First described the principle and operation of the present invention. In the mobile communication system UP-DVR mdcr PO receives the N-CRP from the Node B, and then synchronizes with the Node B based on the code sequence in the received N-CRP. After synchronization, the software extracts the system information of the Node B from the information of the broadcast channel (BCH) transmitted over the P-SSRC during the first channel interval KI0 received from the Node B. The system information of the Node B contains information about the transmitted power of the P-SSRC. When there is data to transmit, the software measures the received power of the P-SSRCN signal and determines the attenuation by comparing the changed received power with information about the transmit power of the P-SSRCCH channel. In the general case, the signal attenuation caused by path loss depends on the distance to the Node B. Thus, by measuring the signal attenuation, the software can estimate the distance to the Node B, as well as estimate the T1 value of the two-way delay, depending on the estimated distance. Therefore, the software calculates the moment of transmission of the V-CRP signal or a specific reference time taking into account the estimated value T1 of the two-way delay. The software transmits a B-CRP signal to Node B at the time of transmission, determined taking into account the estimated value T1 of the two-way delay. In this case, the Node B determines whether the B-CRP signal arrives during the B-CRP, and calculates the T2 information correcting the transmission moment based on the difference (offset) between the initial moment of the B-CRP and the moment of arrival of the received B-CRP signal. This means that the information T2, which corrects the moment of transmission, is the offset between the expected (or desired) time of arrival of the V-CRP signal and the actual time of arrival of the V-CRP signal. Node B transmits information T2, correcting the moment of transmission, to the software via FPACH. When generating the RACH message, the software includes in the RACH message the estimated value T1 of the two-way delay. Having received the information T2 correcting the moment of transmission, the software determines the moment of transmission of the RACH message by summing the received information T2, which corrects the moment of transmission, with the estimated value T1 of the two-way delay. The software transmits a RACH message containing the estimated delay value T1 to Node B at a particular point in time. The Node B transmits the RACH message to the OCRS together with the T2 information correcting the transmission moment. The CSRC calculates the bidirectional delay value τ based on the T2 information correcting the transmission moment and the estimated delay value T1 included in the RACH message. When transmitting the FACH signal to the software, the OCRS determines the transmitted power of the FACH signal based on the bilateral delay value τ, after which it informs Node B a certain level of transmitted power. Node B can transmit the FACH signal to the software at this transmit power level.

Alternatively, the software can also calculate the two-way delay value τ based on the two-way delay value T1 estimated by the software itself and the T2 information correcting the transmission moment received from the Node B. The two-way delay value τ is the sum of the estimated two-way delay value T1 and the correction information T2 the transmission moment, that is, based on the T2 information correcting the transmission moment transmitted by the Node B, the software can calculate the two-way delay value, more accurate with respect to the T1 value of the two-way the delay estimated by the software using the signal R-SSRSN.

Figure 3 shows the exchange of the N-CRP signal between the software and the Node B in the mobile communication system UP-DVR mdcr. According to figure 3, the N-CRP signal received at the software has a time delay, measured from the moment of transmitting 310 N-CRPs to the moment of arrival of 312 N-CRPs, which depends on the distance between the Node B and the software. In order to compensate for the time delay, the software transmits the V-CRP signal to the Node B with the offset of the transmission moment determined during synchronization with the Node B.

Figure 4 shows a method for transmitting a B-CRP signal with a shift in transmission moment. From figure 4 it is clear that the software sets the moment of transmission 412 of the B-CRP signal at T1 earlier relative to the moment of transmission 410, determined during synchronization with Node B. The estimated value T1 of the two-way delay can be estimated based on the value determined by measuring the attenuation of the signal P-SSRSN coming from the Node B. In figure 4 T1 expresses a forward shift.

According to figure 4, the Node B receives the V-CRP transmitted from the software at the time of arrival 414. If it is not possible to receive the B-CRP at the reference time 416, when it should be received, the Node B measures the offset (error) T2 of the arrival, t. e. information correcting the moment of transmission. The offset T2 of the arrival is measured as the difference between the reference moment 416 at which the B-CRP should arrive and the moment 414 of the actual arrival at which the B-CRP actually arrives.

5, the Node B transmits information on T2 via FPACH, and, having received the information T2, the software transmits a RACH message at a point in time calculated by adding T2 to T1. Note that the software transmits the RACH message at the time 514 of the transmission, determined by adding the value of T1, which the software itself had previously determined, with the value of T2 obtained by FPACH. The RACH message contains T1. The Node B receives the RACH message transmitted from the software during the uplink channel interval.

Figure 6 shows the format of the message used when the Node B transmits the offset T2 of the arrival, measured in the above process, to OCRS. In the message, the format of which is shown in Fig.6, in relation to the UP-DVR system, T1 is contained in the area of useful information, and T2 is contained in the header.

The table shows the format of the RACH message that the software transmits to Node B.

The table shows that the T1 information is included in the RACH signaling message or the radio resource control (RRC) message provided in the UP-DVR system. Using the RACH signaling message, the software can transmit to the Node B not only T1 information, but also T2 information. The fact is that, as noted above, the software can obtain the T2 value through the FPACH signal transmitted by the Node B. The method of transmitting T1 information and T2 information using the RACH signaling message is illustrated in FIGS. 11A-11C.

11A shows a method for transmitting only the T1 value by a RACH signaling. In this case, having received the RACH signaling message containing T1 from the software, the Node B adds the software related T2 value to the received RACH signaling message, and then transmits the RACH signaling message with the added value of T2 to OCRS, the control software, which allows OCRS calculate the propagation delay between Node B and the software.

11B shows a method for transmitting T1 and T2 values by means of a RACH signaling. In this case, having received a RACH signaling message containing T1 and T2 from the software, the Node B transmits the received RACH signaling message to the OCRs without using a separate operation, which allows the OCRs to calculate the propagation delay between the Node B and the software.

More specifically, the software stores the T1 value (to be used at the time of transmitting the V-CRP before generating the RACH signaling message) in the RACH signaling message, receives the FPACH, and then reports the T2 value included in the received FPACH signal to the radio resource controller (RRC). The term “RRC”, used in a promising mobile communication system, refers to a device that manages radio resources. The RRC adds the T2 value received by FPACH to the RACH signaling message, and then transmits the RACH signaling message with the added T2 value to the OCD through Node B.

On figs shows a method of calculating T1 and T2, carried out on software, and the subsequent transmission of the calculated values by means of a RACH signaling. This method is basically identical to the method shown in FIG. 11B with the exception of the transmission format. Since the software knows the values of T1 and T2, the software can independently calculate the propagation delay value when transmitting T1 and T2. For example, the software can calculate the propagation delay by adding T2 to T1 and dividing the amount by 2. Alternatively, the software transmits the B-CRP at a given point in time after receiving the N-CRP, and the Node B, having received the B-CRP, calculates the difference between a predetermined (or required) point in time for a specific Node B and the moment of arrival of the B-CRP and reports the calculated software difference by FPACH, which allows the software to calculate the propagation delay value.

7 shows the propagation delay that occurs when PO1 and PO2 transmit B-CRP signals according to an embodiment of the present invention. According to Fig. 7, if PO1 and PO2 transmitted B-CRP signals to Node B at the corresponding transmission times, both shifted by T1, then B-CRP signals undergo different propagation delays. As a result, the B-CRP signal transmitted from PO1 and the B-CRP signal transmitted from PO2 arrive at Node B at different times of arrival. The presence of different propagation delays is due to the fact that the distance between PO1 and Node B differs from the distance between PO2 and Node B. Therefore, T2 for PO1 and T2 for PO2 acquire different values.

Note that, if according to Fig. 7 it is accepted that the B-CRP signal should arrive at the Node B at the required moment of B arrival, then PO1 should transmit the B-CRP signal, decreasing the transmission time offset by the value of T2 determined for PO1, in comparison with the first transmission of the B-CRP signal, when the transmission moment was shifted by the value of T1. Therefore, the Node B must inform PO1 the found T2 value for PO1 by FPACH. Then, PO1 and PO2 transmit RACH messages taking into account the corresponding T2 values, and Node B can correctly receive RACH messages transmitted from PO1 and PO2 during the uplink channel interval.

On Fig shows a method of measuring T2 indicated in Fig.7. According to Fig. 8, if PO1 transmits a B-CRP with a shift of the transmission moment by T1, then the B-CRP can arrive at Node B earlier or later than the reference moment (or the desired arrival time) B. If the B-CRP arrives at Node B earlier than the reference moment B, then the Node B requests PO1 to transmit the B-CRP to T2d later than is required taking into account T1. Otherwise, if the B-CRP arrives at Node B later than the reference moment B, then the Node B requests PO1 to transmit the B-CRP to T2c earlier than is required taking into account T1. Therefore, the arrival of the B-CRP to Node B can be aligned in time. T2 can be determined from equation (1)

B-T2s = T ₂ > 0

B-T2d = T ₂ <0

According to Fig. 8, the value of the difference between the expected (or required) moment of arrival of B and the actual moment of arrival of B-CRP can be defined as leading T2d or lagging T2c.

T2d and T2c can take values of -96 signal elements ≤ T2 ≤ 32 signal elements. The maximum leading value of “-96 signal elements” is determined taking into account the protective period (RF) indicated in figure 2.

The T1 value measured by the SO and the T2 value measured by the Node B can be used to measure the propagation delay between the SO and Node B. The propagation delay between the SO and Node B can be represented in the form of equation (2)

Tsum = T1 + T2

As shown in equation (2), T1 is defined as a value expressing how many signal elements are earlier than the reference (or desired) moment of transmission. The software will transmit a B-CRP signal relative to the time axis of Node B. T2 is defined as the difference between the reference (or required) moment the arrival and actual moment of arrival of the B-PKI relative to the time axis of Node B.

Therefore, using T1, measured by the software, and T2, measured by the Node B, it is possible to measure the value of the propagation delay between the software and the Node B.

The T2 value measured by the Node B is transmitted to the software via the FPACH message. Having received T2 from Node B, the software transmits the RACH message to Node B, having shifted the moment of transmitting the RACH message to T2 so that Node B can receive the RACH message propagating with the expected delay.

The transmission torque offset shown in FIG. 4 can be expressed by the following formula. For example, let T2 be expressed by 8 bits. Then, the value that can be expressed using 8 bits is 2 ⁸ = 256, and at 1/2 resolution, the expressed value can be represented as equation (3)

0≤N≤255.

In this case, it is believed that the range of possible shift of the transmission moment, determined on the basis of T2 measured by the Node B, is -96 signal elements ≤ T2 ≤ 32 signal elements.

Since the value is expressed in 8 bits, the range can be rewritten as follows.

Equation (4)

-192≤Y≤64

T2 = Y × l / 2

N = Y + 192

. Таким образом, если Т2 имеет значение между -96 и 1/2-96, то N задают равным 0, и передают значение 0 посредством 8 битов. Приняв значение 0, ПО может определить, что Т2 имеет значение между -96 и 1/2-96.From equation (4), the T2 range is expressed as

. Thus, if T2 has a value between -96 and 1 / 2-96, then N is set to 0, and the value 0 is transmitted by 8 bits. By accepting a value of 0, the software can determine that T2 has a value between -96 and 1/2/96.

To transmit a RACH message, the software first transmits a V-CRP signal. This means that when a higher level generates a V-CRP signal and transmits a request for a RACH message to the physical layer, the physical software layer transmits a V-CRP signal. When the B-CRP signal is transmitted in this manner, it can be assumed that the RACH message has been generated in advance. However, since the software receives T2 after transmitting the B-CRP signal, the software cannot add T1 and T2 to the RACH message. Therefore, through the RACH message, the propagation delay value measured by T1 and T2 cannot be transmitted. However, T1 is the value that the software can determine before transmitting the B-CRP signal. Therefore, T1 can be added to the RACH.

The present invention provides a method for transmitting T1, measured by software, and T2, measured by Node B, to OCRS. T1, measured by software, as described above, can be added to the RACH message. This means that the software calculates T1 by measuring the attenuation due to path loss of the signal transmitted via the P-SSRC before the formation of the RACH message, after which it adds the calculated T1 value to the RACH message, which is shown in the table. From the table it follows that the information element “RACH measurement results” is part of several messages, for example, cell update messages. The software transmits messages to the Node B via RACH, and the messages contain T1 information. The Node B transmits the RACH message to the OCRS together with the T2 information.

According to another method, the software may transmit a RACH message together with T1 information and T2 information. This means that the software calculates T1 by measuring the attenuation of the signal transmitted over the P-SSRC before the formation of the RACH message, after which it transmits a B-CRP signal, shifting the transmission moment to T1. The Node B calculates T2 by receiving the B-CRP signal, and reports the calculated T2 value to the software using the FPACH message. Having accepted T2, the software generates a RACH message containing T1 and T2, and transmits the generated RACH message to Node B. Node B transmits an RACH message containing T1 and T2 to OCRS. Thus, OCDs can find the value of the two-way delay.

Figure 9 shows the operation of the software in measuring the propagation delay value according to an embodiment of the present invention. According to FIG. 9, it is assumed that the software transmits a B-CRP signal with a shift of the transmission moment by T1 according to the method shown in FIG. 11A.

According to Fig.9 at step 901, the software is synchronized with the Node B using the signal N-CRP. In this process, the software is “aligned” in time with the Node B. Having synchronized with the Node B in step 901, the software in step 902 receives the P-SSRCN signal transmitted by the Node B, after which, in step 903, it analyzes the BCH information contained in the received signal P- SSRSN. BCH is a channel for transmitting system information from Node B to software. System information includes information about the transmitted power of the P-SSRCN signal transmitted by the Node B. The software can calculate the path loss between the Node B and the PO by comparing the information of the transmitted P-SSRCN power with the received P-SSRCN power. After calculating the path loss between the Node B and the software, at step 904 it calculates the estimated value T1 of the two-way delay using the path loss and determines the moment of transmission of the B-CRP signal using the calculated T1. At step 905, the software adds the calculated T1 to the RACH signaling message. The RACH signaling message may contain messages of “direct uplink transmission”, “cell update”, “initial direct transmission”, “request to reconnect to the RRC” and “request to connect to the RRC”, and T1 is added to this RACH message . An example of a RACH signaling message with T1 added to it is shown in the table. At step 906, the software transmits the B-CRP signal at a specific point in time. By transmitting the B-CRP signal to the Node B, the software, at step 907, receives the FPACH signal transmitted by the Node B in response to the B-CRP signal. The FPACH signal contains the T2 value calculated by the Node B in step 906 upon receiving the B-CRP signal transmitted from the software. Upon receiving the FPACH signal, the software determines in step 908 the transmission moment of the physical random access channel (PRACH) using the T2 value extracted from the FPACH signal. The term PRACH, used in a prospective mobile communication system, is a physical RACH transmission channel. At step 909, the software transmits a RACH signaling message containing T1 via PRACH at the time of transmission determined based on T2.

FIG. 10 illustrates the operation of the Node B in measuring the propagation delay value in a CDMA UP-DVR mobile communication system according to an embodiment of the present invention.

According to FIG. 10, the Node B in step 1001 receives the B-CRP signal transmitted from the software, and then in step 1002 calculates T2 based on the difference between the reference (or required) time of arrival and the actual time of arrival of the B-CRP signal. Then, in step 1003, the Node B transmits an FPACH signal during a given downlink channel interval. The FPACH signal contains T2. At step 1004, the Node B receives a RACH message that the software transmitted at the time of transmission, adjusted for T2 transmitted by the FPACH signal. The received RACH message contains a RACH signaling message. At step 1005, the Node B includes information about T2 in the payload area of the RACH signaling message and adds a header to it, thereby forming a RACH signaling frame. At step 1006, the Node B transmits a RACH signaling frame containing T2 information to OCRS. The format of an exemplary RACH signaling frame containing T2 is shown in FIG. 6. Having received the RACH signaling frame transmitted in step 1006, the OCHR computes the propagation delay value between the Node B transmitting the RACH signaling frame and the software transmitting the RACH signaling using T1 and T2 contained in the received RACH signaling frame. The OCDS calculates the bi-directional delay value based on the calculated propagation delay value.

The present invention provides a method for measuring a bi-lateral delay value or propagation delay value by a RACH message transmission process.

However, according to an alternative embodiment, it is also possible to relatively reliably calculate the bi-directional delay value or the propagation delay value even when communication between the software and the Node B is carried out on a dedicated channel (DCH). In this case, the measured value of the two-way delay or the value of the propagation delay can be used to provide software location services. DCH is a channel for transmitting user information or control information from a higher level. When a CDMA UP-DVR mobile communication system communicates via a DCH, the software continuously controls the transmission moment of the uplink DCH by means of a synchronization bias (CC). The CC method allows you to adjust the moment of transmitting the uplink DCH to the SO in such a way that the Node B receives the uplink DCH exactly within the boundaries of the uplink channel interval for the Node B. The procedure for accurately equalizing the moment of the arrival of the uplink channel at the Node B is called the “procedure timing advances. " The correction for the moment of transmission of the uplink channel to the software determined by the time advance procedure is applied after the moment of reception of the downlink channel received from the Node B. The correction, denoted by T, represents the value of the two-way delay between the software and the Node B. Therefore, the value propagation delays equal to T / 2. The bi-lateral delay value or propagation delay value can be transmitted by reporting the highlighted measurement when communicating over the DCH. The report on the selected measurement is sent to OCRS. According to the method for measuring the propagation delay value or the bi-directional delay value when communicating via DCH, the software independently measures the propagation delay value.

In a mobile communication system ШП-ДДР mdcr, the propagation delay value is measured by OCRS, in a mobile communication system ДДЧ mdcr, the value of the propagation delay is measured by Node B. However, in the mobile communication system UP-ДДР mdcr software can independently measure the value of the propagation delay or the value of two-way delay based on the information used in the timing advance procedure. In addition, OCDS requests the software to report the propagation delay value or two-way delay value through a dedicated measurement procedure, and, upon request, the OCRS calculates the propagation delay value or two-way delay value and sends a CSRC message containing the calculated OCD value using the selected measurement report.

The calculated two-way delay value can be used to determine the transmitted power when the OCRS transmits FPACH data to the software. Thus, the OCDS informs the Node B about the transmitted power of the FACH data so that the Node B can transmit the FACH data on the software at the optimal level of transmitted power. In addition, the round-trip delay value can also be used to estimate software location. Additionally, the present invention provides a method for measuring a propagation delay value or a two-way delay value when establishing a dedicated channel.

Although the invention has been illustrated and described with reference to a preferred embodiment, it will be understood by those skilled in the art that it allows various measurements regarding the form and details, but without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (26)

1. A method of measuring the propagation delay value for a frame transmitted from software (user equipment) to Node B in the DDA mobile communication system (operating in time division duplex mode), in which the frame is divided into two subframes, each of which contains many channel intervals and also contains the channel interval of the pilot channel downlink and the channel interval of the pilot channel uplink, which are both between the first channel interval and the second channel interval of many two channel intervals, moreover, the system also includes Node B transmitting a frame with reference to the time axis, and software that, having received a frame from Node B, transmits a frame in response to the propagation delay, the method comprising the steps of enter synchronism with the Node B using the signal of the downlink pilot channel transmitted during the channel interval of the downlink pilot channel, and determine the estimated value T1 of the two-way delay by comparing the transmitted signal power of the physical common channel and in the first channel interval with the received signal power of the physical common channel, the uplink pilot channel signal is transmitted at a time determined by shifting the required transmission moment of the uplink pilot channel signal by the estimated bilateral delay value T1, the correction value T2 is received transmission by means of a direct physical access channel signal (PFKD, FRACH) transmitted from Node B during one channel downlink interval from channel intervals, and transmit the message of the physical random access channel (PRACH), containing the estimated value T1 of the two-way delay, at the time of transmission, determined on the basis of the correction value T2 of the moment of transmission and the estimated value T1 of the two-way delay, which allows the Node B to receive the PRACH message in the initial the moment of one channel interval of the uplink of the set of channel intervals. 2. The method according to claim 1, characterized in that the transmitted signal power of the physical common channel is determined based on system information provided by the broadcast channel in the physical common channel signal. 3. The method according to claim 1, characterized in that the estimated value T1 of the two-way delay is determined on the basis of path losses determined by comparing the transmitted signal power of the physical common channel with the received signal power of the physical common channel. 4. The method according to claim 1, characterized in that the required moment of transmission of the pilot signal of the uplink communication channel is determined based on the input into synchronism. 5. The method according to claim 1, characterized in that the correction value T2 of the transmission moment is determined based on the offset between the moment of arrival of the channel interval of the uplink pilot channel and the desired moment of arrival of the channel interval of the uplink pilot channel. 6. The method according to claim 5, characterized in that the desired arrival time coincides with the initial moment of the channel interval of the pilot channel of the uplink pilot channel. 7. The method according to claim 6, characterized in that the correction value T2 of the transmission moment is determined in the range of displacements of the transmission moments from -96 signal elements to 32 signal elements. 8. The method according to claim 7, characterized in that the value equal to -96 signal elements is determined taking into account the protection period existing between the channel interval of the downlink pilot channel and the channel interval of the uplink pilot channel. 9. The method according to claim 1, characterized in that the moment of transmission of the PRACH message is determined by summing the estimated value T1 of the two-way delay and the correction value T2 of the moment of transmission. 10. A method for measuring the propagation delay value for a frame transmitted by the Node B to software (user equipment) in the DDA mobile communication system (operating in time division duplex mode), in which the frame is divided into two subframes, each of which contains many channel intervals a downlink, a plurality of uplink channel slots, a downlink pilot channel slot and an uplink pilot channel slot, and further comprising Node B, To transmit a physical common channel signal during the first channel interval of a subframe, and software for calculating the estimated value of the bi-lateral delay T1 based on the path loss of the signal of the physical common channel and transmitting the channel interval of the uplink pilot channel using the calculated bilateral delay T1, the method comprising the steps of determining a correction value T2 of a transmission moment based on an offset between the moment of arrival of the uplink pilot channel signal Depending on the required moment of arrival of the uplink pilot channel signal during the channel interval of the uplink pilot channel, the correction value T2 of the transmission moment is included in the signal of the direct physical access channel (PFCA, FPACH) and the FPACH signal is transmitted to the software within one channel the downlink interval from the downlink channel intervals, receive the message of the physical random access channel (FKPD, PRACH) containing the estimated value T1 two-way delay transmitted from the software to my The transmission coefficient determined based on the correction value T2 of the transmission moment and the estimated value T1 of the two-way delay during one channel interval of the uplink from the channel intervals of the uplink, and the estimated value T1 of the bilateral delay and the correction value T2 of the transmission included in the message are transmitted PRACH, to the radio network controller (RNC) to which the software belongs, together with the RACH signaling message, which allows the RNC to determine the two-way delay between the Node B and the software. 11. The method according to claim 10, characterized in that the desired moment of arrival coincides with the initial moment during the channel interval of the uplink pilot channel. 12. The method according to claim 10, characterized in that the correction value T2 of the transmission moment is determined in the range of displacements of the transmission moments from -96 signal elements to 32 signal elements. 13. The method according to p. 12, characterized in that the value equal to -96 signal elements is determined taking into account the protective period existing between the channel interval of the pilot channel of the downlink and the channel interval of the pilot channel of the uplink. 14. The method of claim 10, wherein the two-way delay value is determined by summing the estimated two-way delay value T1 and the correction moment value T2 of the transmission. 15. A method of measuring the propagation delay value when exchanging frames between software (user equipment) and Node B in the DDA mobile communication system (operating in time division duplex mode), which contains a frame divided into two subframes, each of which contains many channel intervals a downlink, a plurality of uplink channel slots, a downlink pilot channel slot and an uplink pilot channel slot, and further comprising green B, transmitting the physical common channel signal during the first channel interval of the subframe, and software calculating the estimated bilateral delay value T1 based on the path loss of the physical common channel signal and transmitting the uplink pilot channel channel interval using the calculated bilateral delay value T1 , a method comprising the steps of transmitting the uplink pilot channel signal from the software to the Node B at the time of transmission, defined as the required moment of transmission of the pi signal from the uplink channel with the addition of the estimated bidirectional delay value T1, is determined by the Node B to adjust the transmission moment T2 based on the offset between the moment of arrival of the uplink pilot channel signal and the desired moment of arrival of the uplink pilot channel signal from Node B to software, the found correction value T2 of the transmission moment together with the signal of the direct physical access channel (PFKD, FPACH), over a given downlink channel interval and communications, transmit from the software to the Node B a physical random access channel message (FPCD, PRACH) containing the estimated value T1 of the bilateral delay at the time of transmission, determined on the basis of the correction value T2 of the moment of transmission and the estimated value T1 of the bilateral delay received by the FPACH signal , receive on the Node B the PRACH message at the initial moment of the given channel interval of the uplink, and transmit from the Node B to the radio network controller (RNC) to which the software belongs, the estimated value T1 is two-way erzhki correction value T2 and the time of transmission, message included in the received PRACH, together with the signaling channel of the random access message (SDB, RACH), which enables the RNC to determine the round trip delay between the UE and the Node B. 16. The method according to p. 15, characterized in that the desired moment of transmission of the signal of the pilot channel of the uplink communication is determined based on the input into synchronism. 17. The method according to clause 15, wherein the desired moment of arrival of the uplink pilot channel signal coincides with the initial moment of the channel interval of the uplink pilot channel. 18. The method according to clause 15, wherein the correction value T2 of the transmission moment is determined in the range of displacements of the transmission moments from -96 signal elements to 32 signal elements. 19. The method according to p. 18, characterized in that the value equal to -96 signal elements is determined taking into account the protection period existing between the channel interval of the pilot channel of the downlink and the channel interval of the pilot channel of the uplink. 20. The method according to p. 15, characterized in that the moment of transmission of the message of the physical random access channel (FKPD, PRACH) is determined by summing the estimated value T1 two-way delay and the correction value T2 of the moment of transmission. 21. A device for measuring the value of the propagation delay when exchanging frames between software (user equipment) and Node B in the DDA mobile communication system (operating in time division duplex mode), containing a frame divided into two subframes, each of which contains many channel downlink slots, a plurality of uplink channel slots, a downlink pilot channel slot and an uplink pilot channel slot, and further neighing Node B transmitting a signal of the physical common channel during the first channel interval of the subframe, and software calculating the estimated value T1 of the two-way delay based on the path loss of the signal of the physical common channel and transmitting the channel interval of the uplink pilot channel taking into account the calculated value of the T1 bilateral delays, a device containing software transmitting the uplink pilot channel signal at the time of transmission, defined as the required transmission moment of the uplink pilot channel signal communication with the addition of the estimated value T1 of the bilateral delay, and the transmitting message of the physical random access channel (FKPD, PRACH) containing the estimated value T1 of the bilateral delay at the time of transmission, determined on the basis of the correction value T2 of the moment of transmission and the estimated value T1 of the bilateral delay received by means of a direct physical access channel signal (PFKD, FPACH), Node B determining the correction value T2 of the transmission moment based on the offset between the moment of signal arrival the uplink slot channel and the desired arrival time of the uplink pilot channel signal, transmitting a certain transmission timing correction value T2 together with the FPACH signal during a given downlink channel interval and a two-way delay estimated value T1 and transmission timing correction value T2, included in the PRACH message received at the start of this uplink channel interval to the radio network controller (RNC) together with the RACH, RNC signaling frame, a receiving RACH signaling frame and determining a two-way delay between the software and the Node B based on the estimated two-way delay value T1 and the transmission timing correction value T2 included in the received RACH signaling frame. 22. The device according to item 21, wherein the desired moment of transmission of the signal of the pilot channel of the uplink communication is determined based on the input into synchronism. 23. The device according to item 21, wherein the desired moment of arrival of the uplink pilot channel signal coincides with the initial moment of the channel interval of the uplink pilot channel. 24. The device according to item 21, wherein the correction value T2 of the transmission moment is determined in the range of displacements of the transmission moments from -96 signal elements to 32 signal elements. 25. The device according to paragraph 24, wherein the value equal to -96 signal elements is determined taking into account the protection period existing between the channel interval of the pilot channel of the downlink and the channel interval of the pilot channel of the uplink. 26. The device according to item 21, wherein the instant of transmission of the message of the physical random access channel (FKPD, PRACH) is determined by summing the estimated value T1 of the bilateral delay and the correction value T2 of the moment of transmission.

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