JP2001501419A - Method and apparatus for pre-correcting timing and frequency in a communication system - Google Patents

Abstract

(57) Abstract Pre-correct timing and frequency in a communication system (100) employing multiple satellites (116, 118) to reduce timing and frequency instability due to satellite motion Methods and equipment. The transmit signal (410) is pre-corrected or corrected (342) to account for effects based on known satellite motion as a transmit signal propagating from the transmitter (120) to the satellite (116). Elimination of these effects reduces the amount of instability in the transmitted signal when it reaches the receiver (124), facilitating the task of signal reception.

Description

DETAILED DESCRIPTION OF THE INVENTION      Method and apparatus for pre-correcting timing and frequency in a communication system                                Background of the Invention I. Field of the invention   The present invention relates generally to spread spectrum communication systems, and in particular, The present invention relates to reception of a communication signal in a state where Doppler exists. Furthermore, this invention New to pre-correct the time and frequency of communication signals to compensate for the above signal Doppler On the improved method. II. Description of related technology   Typical conventional terrestrial terrestrial, such as wireless data systems, ie telephone systems The communication system is located in a plurality of predetermined geographical areas or cells, Using a plurality of base stations, also called cell sites, one or more user terminals or systems It relays communication signals to system subscribers. In addition, general satellite base traffic The communication system uses multiple base stations, called gateways, and multiple satellites. To relay communication signals between the plurality of gateways and one or more user terminals. You. A plurality of base stations and gateways, each user terminal has another user terminal Or to other connected communication systems, such as the public switched telephone network. Providing a communication link. The user terminal of such a system is of a fixed type, Or a mobile phone, such as a mobile phone. Placed away from toe.   Granted on February 13, 1990, "Spectrum using satellite or terrestrial repeater US Patent No. 4,901,307 entitled "Lamb Spread Multiple Access Communication System" And filed January 4, 1995, entitled "Individual Receive Phase Time and Energy Spectrum Transmitted Power in Spread Spectrum Communication System Following Demand Patent Application Serial No. 08 / 368,570 entitled "Method and Apparatus for Using Some communication systems, as disclosed in US Pat. (CDMA) spread spectrum signal is used. These U.S. patents and U.S. All of the requests have been assigned to the assignee of the present invention, and are set forth in the following description. Used as a reference.   In a typical spread spectrum communication system, a carrier signal for transmission is referred to as a communication signal. And modulating one or more preselected pseudo-noise (PN) code sequences To modulate or spread the information signal over a given spectral band. Known The PN code spreading, which is a spread spectrum transmission method, is more non-uniform than the data signal bandwidth. Generates a transmission signal that always has a large bandwidth. Base station or gateway In the communication link between a and the user terminal, a PN spreading code or a binary sequence is used. To signals transmitted by different base stations or different beams Identify the signal transmitted over it, as well as identify the multipath signal.   A typical CDMA spread spectrum system uses a channelization code. The forward link (that is, user terminal traffic from the base station or gateway). Within one cell or satellite sub-beam in the signal path to the Signals for different user terminals. Each user transceiver has its own By using the channelized orthogonal code, the own code provided on the forward link can be used. It has orthogonal channels. The signals transmitted through these channels It is usually called a traffic signal. Paging, synchronization, and system Additional forward link channel or forward direction for other signals sent to the user A directional link signal is provided. Also, usually supplement the above channelization code. The Walsh function is used for this.   Details of the operation of this type of transmission device are described in "Signaling in CDMA Cellular Phones". US Patent No. 5,103,459 entitled "Systems and Methods for Generating Waveforms" Issue. This U.S. patent is assigned to the assignee of the present invention. Yes, and will be used as a reference in the following description.   CDMA spread spectrum communication system as disclosed in the above mentioned patents Uses coherent modulation and demodulation for forward link user terminal communications. Are considering. In a communication system making such an attempt, a pilot The carrier signal, in short, the pilot signal is the coherent of the forward link signal Used as a phase reference. Pilot signals usually do not include data modulation. Signal and is referenced by the gateway or base station over the entire area of coverage. Conveyed as   The pilot signal is used for initial system synchronization and for the base station or gateway. To get time, frequency, and phase tracking of other signals sent by Used by user terminals. Tracking of pilot signal carrier The phase information obtained from the signals can be used for other system signals or traffic (data) signals. It is used as a carrier phase reference when performing coherent demodulation of signals. this The technology shares a common pilot signal as a phase reference for many traffic signals. To reduce costs and provide a more effective tracking mechanism. Can be offered. In general, a single pilot signal should be used for each frequency used. Delivered by the base station or gateway and transmitted by CDMA channel or It is called a boom beam, and from the source or gateway of that frequency Are shared by all user-end received signals.   If the user terminal is not receiving or transmitting traffic signals, These signals can be implemented using one or more signals known as Information can be transmitted to the terminal. For example, call for a specific mobile phone If there is a paging signal, the base station or gateway will Switch between mobile phones. The paging signal indicates the presence of the call and which traffic Used to indicate whether to use a network channel. Used to distribute system overhead information with specific messages You. One communication system has a plurality of paging signals or channels. May be. Also, to transmit system information effective for facilitating time synchronization, A period signal can also be used. All these signals are similar to pilot signals , Function as a shared resource.   The user terminal sends the access signal over the reverse link to To respond to messages on the ringing signal. That is, from the user terminal It is a signal path to a local office or a gateway. Also, the access signal is When a terminal initiates a call, it is also used by these user terminals to access Sometimes referred to as a probe. Normally, long PN codes are used for reverse link traffic. Used to create a fic channel. At the same time, use one set of orthogonal codes The improved M-ary modulation scheme can be used to improve reverse link data transmission. Wear.   In either communication system, the forward link communication signal is transmitted by the user terminal. Down-converted to the baseband frequency for further processing. It is. When downconverted, these signals are digitally processed and Used to detect and cooperate with the pilot signal or received signal. It is used to demodulate paging signals, synchronization signals, and traffic signals. During demodulation, a PN spreading code is provided to aggregate these signals and A channelization code is associated with these signals to provide data.   In such a system, the reception, downconversion, and demodulation processes are performed. For accurate processing, the user terminal must have a common frequency reference and common timing. Sharing the reference with the base station or gateway transmitting the signal to be processed Need to be In other words, since information is transmitted in the phase of the signal carrier, the carrier The frequency must be accurately detected, and the relative phase position of multiple carriers Must be decided. Without a fairly accurate frequency adjustment, the carrier It cannot be reliably removed, and the digital signal can be accurately aggregated and demodulated. I can't.   Since the PN spreading code is given to the signal one after another, the timing of the signal is Decide to properly despread or demodulate the spreading code from the signal that supplies the data. Must be done. PN spreading code and orthogonal channelizing code It can not be accurately removed without the need for severe system timing or signal synchronization. Code is When given with incorrect synchronization, the signal appears as just noise and no information Not carried. Satellites, user terminals and codes used in such systems You can also set the timing offset position, replace time or related time It depends on the exact knowledge. The user terminal must determine the appropriate clock value, event timing, And a localizer that maintains relevant time values for base station or gateway timing Rely on the accuracy of oscillators, and absolutely chronological history and relationships.   Communication systems that use satellites in non-geostationary orbits require user terminals and satellite operation. High degree. The associated action results in a net substantial Doppler component, or Shift within the carrier frequency of the signal in the communication link. These Doppler components The frequency of the carrier signal varies depending on the user terminal and satellite operation. Yields an uncertain value, i.e., an uncertain frequency, more simply.   In addition to such a frequency shift, the Doppler effect also affects the solar time, ie, P It occurs at the timing of shifting to various codes including N codes, symbols, etc. These visual solar time shifts are referred to as code Doppler. In particular, the code Doppler is the effect of satellite operation introduced into the baseband signal. Therefore, The code does not arrive at the receiver at the correct code timing.   In addition to Code Doppler, satellite operation also affects the propagation of signals for communication links. A large amount of uncertainty in delay or timing uncertainty results. Propagation delay From the minimum when the satellite is above the user terminal connected to the gateway, Change to maximum when satellite is level with user terminal connected to gateway . In other words, the propagation delay has been reduced to the minimum distance from the gateway to the satellite When it is at a minimum. Similarly, the propagation delay is the maximum distance between the gateway and the satellite. It becomes the maximum when it becomes.   In order to obtain a communication signal in a spread spectrum communication system, a communication system The system must detect the carrier frequency of the signal and the synchronization timing of the signal. No. Accurate by comparing signals in general communication systems with "hypotheses" The "search" of frequency and timing is based on various fixed wave numbers and uncertainties. It has a timing value. Highest mutual to signal above a preset threshold Hypotheses involving intersystems determine the exact frequency and timing of signal despreading and demodulation. Including.   However, typical communication systems up to now have relatively small frequencies and Due to timing uncertainty, a relatively small “search space”, ie, timing Face the setting and frequency hypothesis. For example, terrestrial communication systems or satellite communication The communication system has a timing uncertainty of 1 to 2 ms or more, and 1 A geostationary satellite showing Doppler uncertainty on the order of one millionth is used. Comparison In a communication system using non-geostationary satellites, a value of 10 to 20 ms or more is used. Timing uncertainty and Doppler uncertainty of about 10 ppm or more Show qualitative. Therefore, all other things are equal and communication systems using non-geostationary satellites System is 100 or more times larger than the search space of a terrestrial or geostationary communication system. It has a search space of the size of the above.   A larger search space takes longer to acquire a signal, or a part of the search space. Requires one of the decoding search receivers that works in parallel with the minute. None of these Both are not preferred.   To reduce the search space of communication systems operating under high Doppler conditions A method and apparatus are needed.                                Summary of the Invention   The present invention uses Doppler for related operations of satellite repeaters and user terminals. Acquiring signals in a communication system to be tested. This type of system Frequency uncertainty due to changes in Doppler shift and propagation delay due to related operation It has a wide range of gender and timing uncertainties. The present invention relates to a communication system. The range of frequency and timing uncertainties in   A feature of the present invention is that it further determines frequency and timing uncertainties. A search receiver is not required. This results in reduced frequency uncertainty A search space is provided that includes a range of gender and a range of timing uncertainty. Therefore , To obtain the signal, a small number of frequency and timing hypotheses must be searched. No. This reduces the time required for signal acquisition.   According to an embodiment of the present invention, a transmitter located at a gateway of a communication system Pre-corrects the frequency of the forward link signal and provides a link between the satellite and the gateway. Compensate for Doppler shift for cropping. Satellite-related operations related to the gateway Because the signal is well known, when the signal reaches the satellite, Of the signal is not exposed to any Doppler shift of the In other words, the upper link portion of the forward link signal (eg, The portion of the forward link to the star) is reserved by the transmitter to compensate for the Doppler shift. Is corrected.   However, the relevant operation of satellites with respect to user terminals is well known. Obedience Therefore, the downlink portion of the forward link signal is relayed by the satellite to the user terminal, That is, when transmitted, the signal is known due to the associated operation between the satellite and the user terminal. Not exposed to a Doppler shift. Therefore, according to the invention, the forward direction Correcting the frequency of the upper link portion of the link signal in advance reduces the uncertainty of the frequency. Instead of removing the whole, the whole in the forward link signal at the user terminal Reduce the uncertainty of the frequency across. Pre-correcting the frequency can reduce signal acquisition Reduces search space for attempted receivers.   According to another embodiment of the present invention, a transmission located at a user terminal of a communication system The transmitter transmits a reverse link signal whose carrier frequency has been pre-corrected, To compensate for the Doppler shift for the related operation between. This is two things Achieved by one of the laws. The user terminal can use various methods. Notice the satellite's associated activity or see a drop in the lower link portion of the forward link signal Adjust the reverse link signal based on the error. In any case, the user terminal , Effectively remove Doppler from the upper link portion of the reverse link signal. in this case, The upper link portion of the reverse link signal reaches the satellite without any apparent Doppler However, the lower link portion is exposed to Doppler.   According to yet another embodiment of the present invention, the transmitter at the gateway has a forward The timing of the upper link portion of the link signal is corrected in advance. In this embodiment, the signal The timing of the signal is continuously adjusted and the signal is used by the communication system Some satellites arrive at the same time as satellite time. Therefore, the transmitter passes through each satellite Adjusts the timing of the signal transmitted to the user terminal so that the signal Synchronization is performed on each satellite at a preset time regardless of the distance to the satellite. Follow Thus, the signal arrives at each satellite substantially simultaneously. In many cases this means , Signals are transmitted to the various satellites at the gateway at different times.   One of the functions of pre-correction of timing is that the Some reduce the timing error in the terminal. Forward link communication Since the timing of the uplink portion of the signal is known, the error Only occurs in the downlink portion of the forward link. Like this, Pre-correction reduces the timing error of the forward link signal by almost half. Can be reduced.   Subsequently, a pre-correction of the signal timing in the CDMA communication system is performed. And virtually synchronize any other satellite regardless of the distance between the gateway and the satellite Provide a PN spreading code sequence to reach a specific satellite at departure time Can be offered. In other words, the uplink of the forward link signal on the satellite The link does not show any code Doppler. In this way, the receiver Correct only Doppler phenomenon (experience) in the downlink part of word link signal Just do it. This allows the user terminal to track the timing of the receiver. This reduces the loop requirements.   In yet another embodiment of the present invention, the transmitter at the user terminal is a reverse link. The timing of the lock signal in advance. In this embodiment, the reverse link signal The signal is adjusted continuously, so that the signal is in satellite time with departure time Each satellite arrives substantially synchronously with satellite time. This is the user terminal That each user terminal transmits signals at different times based on the distance between the Means. For the forward link, the timing And the presence of code Doppler in the reverse link signal. .   In a preferred embodiment of the present invention, the timing and frequency This is performed on the uplink portion between the drink signal and the reverse link signal. Ta This pre-compensation reduces the instability and frequency instability by almost half, and The overall survey area is reduced to almost a quarter. As a result, the hardware It provides substantial savings in cost and acquisition time.         BRIEF DESCRIPTION OF THE FIGURES   The features, objects, and advantages of the present invention will be described in more detail with reference numerals being consistently given. It will become apparent from the drawings described.   FIG. 1 shows a typical communication system used in the present invention.   FIG. 2 shows an exemplary transmitting device used in the user terminal.   FIG. 3 is a typical transmission / reception used for gateway or base station The device is shown.   FIG. 4 is the forward link and reverse link between the gateway and the user terminal Is shown.   FIG. 5 relates to the forward link signal when frequency pre-correction is not performed. The various frequencies associated are shown.   FIG. 6 relates to the forward link signal when the frequency pre-correction is performed FIG.   FIG. 7 is frequency pre-correction for forward link transmission from gateway Are shown.   FIG. 8 is a frequency pre-correction for the reverse link transmission from the gateway. Each step is shown.   FIG. 9 is the forward link and river when no pre-adjustment was made. The transmission of a slink is shown.   FIG. 10 is traffic (traffic) whose time has been pre-corrected according to the present invention. Fig. 4 shows transmission of a forward link and a reverse link for a channel.   FIG. 11 is an access channel whose time has been pre-corrected according to the present invention. And transmission of a forward link and a reverse link for transmission.   FIG. 12 is a process for correcting the advance time of the forward link transmission from the gateway. Shows the process.   FIG. Reference numeral 13 denotes each step of the advance time correction of the reverse link transmission from the gateway. Is shown.   Detailed description of the invention   The present invention relates to a communication system in which timing and frequency Method and apparatus for pre-correcting timing and frequency to reduce stability It is. The present invention accomplishes this, in part, by providing a forward link signal, Doppler phenomenon occurs in the uplink part of the transfer signal from the gateway to the satellite. This is performed by determining and correcting the portion that has been changed. Thus, all forwards The drink signal arrives at the satellite with a similar frequency precorrection.   The downlink portion of the forward link signal is the associated activity between the satellite and the user terminal. No correction is made since the work is known. Downlink part is not corrected However, all frequency uncertainties in the forward link are significantly reduced (almost half Is done). This requires a forward link signal receiver to receive the signal Search space can be reduced.   The present invention is suitable for a communication system using low earth orbit satellites. But However, as will be apparent to those skilled in the relevant art, the concepts of the present invention may be used for communication purposes. It can also be applied to unused satellite systems. The invention relates to the frequency of the received signal. There is sufficient similar motion to impact, and there is sufficient instability in signal propagation delay If so, the satellite system of non-LEO orbiting satellites and the non-satellite repetition (repeater The present invention can be similarly applied to a system.   Preferred embodiments of the invention are described in detail below. In certain processes, The configuration and arrangement are discussed, but this is done for illustrative purposes. Seki Those skilled in the art will also understand other steps, and configuration and arrangement will depart from the spirit and scope of the present invention. The present invention can be used without being performed. The present invention has a position determination function Can be used in the field of wireless information and communication systems, satellite and global It can be used in mobile phone systems. A good application is to use satellites For mobile or portable telephone services, which are typical examples of transfer To a CDMA wireless spectrum communication system.   FIG. 1 shows an example of a wireless communication system to which the present invention is effectively applied. This communication system The system uses communication signals in CDMA format, but the present invention is limited to this format. Not. One form of the communication system 100 shown in FIG. 112, two satellites 116 and 118, and two corresponding gateways Hubs 120 and 122 communicate with two remote user terminals 124 and 126 Do. Generally, base stations and satellite / gateway are components of a separate communication system. Called terrestrial and satellite-based, but this is essential It is not a condition. The total number of base stations, gateways, and satellites depends on the desired system. It depends on the model and other factors known in the art.   User terminal 124 may be a cellular telephone, data transceiver, or paging or location. It is a portable device or a vehicle-mounted device if desired, including a position determination receiver and the like. Where the user The terminal is shown as a mobile phone. However, the gist of the present invention is that Applicable to fixed units used indoors and outdoors where screws are desired .   Generally, the beams from satellites 116 and 118 will have a predetermined pattern of geographic differences. Cover an area. Beams of different frequencies (CDMA channels or (Called "beams") can be directed to overlap in the same area. Of course, the beam coverage or service area for multiple satellites, or The tena pattern is based on the design of the communication system, the types of services to be provided, and the specifications. All or part of a given area, depending on whether or not source diversity is achieved It is designed to overlap.   48 or so on a low earth orbit (LEO) on eight different elliptical planes Various multi-satellite communication systems, including one that uses more satellites, Proposed. However, the techniques of the present invention may be applied to various satellite systems and other elliptical distances. And how it applies to gateway configurations including arrays. It is easily understood. At the same time, the present invention provides a terrestrial-based The same applies to systems.   In FIG. 1, several signal paths include user terminals 124 and 126 and a base station. Between 112, including gateways 120 and 122 or via satellites 116 and 118 It is shown for the purpose of establishing communication. Base station user terminal communication link , Shown by lines 130 and 132. Satellites 116 and 118 and user terminal 1 Satellite user terminal communication links between 24 and 126 are on lines 140, 142 and 14 4. Between gateways 120 and 122 and satellites 116 and 118 Gateway satellite communication links are indicated by lines 146, 148, 150 and 152. Have been. Gateways 120 and 122 and base station 112 can be one-way or Used as a two-way communication system, or simply a message or date and time Used to communicate to terminals 124 and 126.   FIG. 2 shows an example of the transceiver 200 used in the user terminal 106. Tiger Transceiver 200 includes at least one antenna 210 for receiving a communication signal. use. This communication signal is transferred to the analog receiver 214, where the down-con It is downconverted, amplified and digitized. Send / receive element 212 is generally used to perform both transmit and receive functions on the same antenna. Can be But use separate antennas operating at different transmit and receive frequencies It may be a system.   The digital communication signal output by the analog receiver 214 has at least one Data receiver 216A and at least one digital searcher receiver 2 18 is transferred. Accept other digital data receivers 216B-216N Desired level of signal diversity, depending on the level of complexity of the unit Can of course be used to obtain   At least one user terminal control processor 220 includes a data receiver 216A. 216N and the search receiver 218. The control processor 220 Meaning, basic signal processing, timing, power and handoff control or regulation, and signal Provides selection of frequency used for transport. Control processor 220 The other basic control functions performed are PN codes for processing communication signal waveforms. Selection or manipulation of a sequence or diagonal function. Control processor 220 signals Processing includes determining relative signal strength and calculating corresponding various signal parameters. Can be. Calculation of signal parameters such as relative timing and frequency To achieve increased efficiency or speed or improved allocation of control processing resources May be provided with additional or dedicated circuitry.   The outputs of the digital data receivers 216A to 215N are digital The signal is supplied to the baseband circuit 222. User digital baseband circuit 222 Is used to transfer information from and to the user's user terminal It includes a processing element and a providing element. That is, those elements are temporary or long-term memory Signals, such as data storage elements, display screens, speakers, keypads, etc. Input / output devices such as a mobile terminal and a handset, an A / O element, a vocoder, Other audio and analog signal processing elements, etc. It is a general element that constitutes each part of the road. Diversity signal processing is adopted In this case, the user digital baseband circuit 222 includes the diversity combiner (d iversity combiner) and a decoder. Some of these elements Under the control of the control processor 220 or by communicating with the control processor 220 Some work.   An output message or communication signal where voice or other data originates from the user terminal The user digital baseband circuit 222, when prepared as Used to receive, store, process, and create data. User digital base The band circuit 222 converts this data into transmission data that operates under the control processor 220. Provided to the controller 226. The output of transmit modulator 226 is transferred to power controller 228. Sent. The controller 228 sends output power control to the transmission power amplifier 230. Where the final transmission of the output signal from the antenna 210 to the gateway takes place. Will be   As described later, in order to introduce the embodiment of the present invention, one user terminal 200 is provided. Or a plurality of pre-correction elements or pre-correctors 232 and 234 Can also be used. Preferably, the pre-correction element 232 is a digital power controller. Used to adjust the frequency of the digital output of the It is. The baseband spectrum information including the frequency adjustment is transmitted to the transmission power amplifier 230 To the appropriate center frequency during up-conversion performed in Is done.   Pre-correction or frequency adjustment is performed in a manner common in the art. For example, reserve The correction can be made by a complex signal rotation. This is the signal^{j ωt}Over Is equivalent to Where ω is the known satellite ephemride and desired channel Calculated based on channel frequency. This is because the communication signal is in-phase channel (I ) And very useful when treated as a quadrature phase channel (Q) is there. Digital synthesizers can be used directly to generate some of the rolling products. Wear. Alternatively, perform a series of individual rotations by performing binary shifts, additions, and subtractions, A coordinate rotation digital computing element that achieves a combined desired rotation can be used.   Alternatively, transmit power amplifier 2 may be used to adjust the frequency of the outgoing signal. A pre-correction element 234 can be provided in the transmission path of the 30 outputs. This is equivalent to up-conversion or down-conversion of the transmitted waveform. This can be achieved by using known techniques. While adjusting the waveform, Often there is a series filter used, where the frequency change is Change the frequency of the analog transmitter output, as it may affect the filtering process. It can be difficult. In this alternative, the pre-collection element 2 32, 234 are analog up-conversion frequency selection or control mechanisms And a part of the modulation stage (230) of the user terminal can be configured. Thus, in order to convert a digital signal to a desired transmission frequency in one step, Appropriately adjusted frequencies will be used.   As will be described in more detail below, the user terminal 200 also determines the timing of the outgoing signal. Pre-correction elements 232 and 234 arranged on the transmission path for Can be adopted. Here, the timing precorrection circuit Constituting a part of the element. This is because adding or subtracting delays in the transmitted waveform This can be achieved by known techniques. Furthermore, the pre-collection element 232 and And additional pre-collection elements for additional time (not shown) similar to 234 , As needed, to serve the purpose of changing the timing. Precorrection of time can be done with or Relative timing of signal, ie PN code, without number pre-correction Can be used to change   However, timing adjustments are typically performed when the signal is generated at baseband and power is Generation of control processor adjustment code when output by controller 228 Achieved by having the timing and timing or other signal parameters Is done. Controller 220 may, for example, determine when a code is generated. And determine their timing and application to the signal, and when the signal is transmitted Activated by modulator 226 and controlled by power controller 228 You can determine if it will be transmitted to the satellite.   At least one time reference element 238 stores time information such as date and time. Can be used to generate and store. This time information is the satellite's position in a known orbit. Can be used to determine the This time can be updated and stored periodically. Wear. And in some applications, universal time of GPS receiver (UT) signals can be used as part of this process. This time again , Can be periodically supplied to the user terminal by a gateway. In addition When the user terminal enters the stop mode, that is, when the terminal is turned off, The current time can be stored. And this current time is various time Can be used to determine dependent signal parameters.   As shown in FIG. 2, a local or reference oscillator 240 , Analog transmitter 230, and clock used by time reference element 238 Used as a reference for the circuit. Oscillator 240 also includes timing circuit 2 42 is also used as a frequency standard or reference for It generates timing signals for other stages or processing elements. These Time tracking circuit or digital receiver 21 as an example of a stage or processing element. 6A-N and correlator in 218 or transmit modulator 226, time reference element 23 8, and the control processor 220.   As is well known in the art, known circuits are used to form the desired timing signals. By using the configuration, the frequency of the oscillation output can be adjusted. These timings The signal is generally treated as a clock signal for many circuits. Taimi Circuit 242 may be used under process control to generate delays or blockages. Or for the purpose of proceeding within the relative timing of the clock signal. This allows time tracking to be adjusted by a predetermined amount. This is also Generally, you should advance or delay from "normal" timing for one or more chip periods. Code is allowed. Thereby, a PN code, that is, a code is formed. Chips can be applied at different timings as appropriate.   1 measured for the received communication signal, ie, one or more shared resource signals Information or data corresponding to the above signal parameters is obtained by various techniques well known in the industry. It can be sent to the gateway using techniques. For example, this information is separate Can be transmitted as an information signal or can be transmitted by the user digital baseband circuit 222. Can be added to other messages created. Alternatively, this information Under the control of the control processor 220, the transmission modulator 226 or the transmission power controller It can be inserted as a predetermined control bit by the roller 228.   The data receivers 216A-N and the search receiver 218, together with the signal correction elements , Configured to modulate and track a particular signal. Digital receivers 216A-N While used to modulate other signals with the detected pilot signal, Search receiver 218 may have a fixed pilot signal or other relatively fixed pattern. Used to search for strong signals. The data receiver 416 will Can be assigned to applications that track or modulate the signal. Therefore, The output of these units is used to determine the energy or power of the pilot or other signals. Can be monitored for the purpose of determining the frequency. These receivers are currently Processor 22 for providing frequency and timing information and for the signal being demodulated A frequency tracking element that can be monitored to control zero is employed.   The control processor 220 can be scaled to the same frequency band, if necessary. When such information is received from the expected reception frequency or oscillation frequency, Used to determine how much the number shifts. Frequency error and the This and other information related to the puller shift may include one or more errors / Dopplers. It can be appropriately stored in the stage or the storage element 236. This This information is used by the control processor 220 to adjust the oscillation operating frequency. Or transmit to gateway or base station using various communication signals can do.   FIG. 3 illustrates the transceivers used in gateways 120 and 122 or base stations. 2 shows an example of the device 300. This device is well known in the art and is disclosed in the aforementioned patents. I have. For example, further details regarding the operation of such devices can be found in Apr. 1992. U.S. Patent No. 5,103,459, issued on March 7; "CDMA cellular telephones. Systems and Methods for Generating Signal Waveforms in the United States. The national patent has been assigned to the same assignee as the assignee of the present invention, and the contents of this U.S. Patent Is disclosed in the present application.   Portions of the gateways 120 and 122 shown in FIG. It has one or more analog receivers 314 connected to the antenna 310. these Communication signal is later down-converted using various methods well known in the industry. , Amplified and digitized. Multiple antennas 310 may be used in some communication systems. Used in the system. Digitized output by analog receiver 314 The signal is transmitted to at least one digital receiving module (generally indicated by dashed line 324). (Shown) are provided as inputs.   Although several variations are well known in the art, each digital Manages communications between the gateways 120, 122 and one of the user terminals 124, 126. Corresponding to the signal processing elements used to process the signals. One analog receiver 314 , Can be provided to a number of digital receiving modules 324. And Many such modules are handled at all satellite beams and at any time To accommodate possible diversity mode signals where possible In general, it is used in the gateway 120. Each digital receiving module 324 includes one or more digital data receivers 316 and a search receiver 318. are doing. The search receiver 318 typically provides an appropriate change in signals other than the pilot signal. Explore modes. When embedded in a communication system, multiplex digital data The receivers 316A to 316N are provided for diversity signal reception. Used for   The output of data receiver 316 is provided to subsequent baseband processing element 322. . The baseband processing element 322 is a well-known device. Are not shown. An exemplary baseband device is a diversity coupling Including multi-path and decoder to combine multipath signals into the output for each user . This exemplary baseband device also typically has a digital switch or network. And an interface circuit for supplying output data to the network. For example, Vocoders, data modems and digital switching storage components, but not limited to Other known elements that are not included are part of the baseband processing element 322. May be formed. These elements are connected to one or more transmitting modules 334. To control or direct the transmission of the data signal.   The signal to be transmitted to the user's terminal may be one or more suitable transmissions Each is connected to a module. A typical gateway has many such When using the transmission module 334, a number of user terminals 124, 12 6 and, sometimes, ready for some satellites and direction signals. Have been. Multiple transmission modules used by gateways 120, 122 334 depends on the complexity of the system known in the art, the number of satellites considered, It is determined by factors such as the number of users and the degree of diversity selected.   Each terminal module 334 transmits the spectrum module data for transmission. And a transmitting module 326 for spreading the Coupled to a digital transmit power controller 328 that controls the transmit power applied. Output. The digital transmission controller 328 has an interface Gives a minimum level of power to reduce and allocate resources You. However, the digital transmission controller 328 includes a transmission path (path) and Adequate level of power needed to compensate for attenuation in other path transmission characteristics Is given. If at least one PN oscillator 332 is spreading the signal Is used by the transmission module 326 at. This code transmitter is Tway 12 2, 124 or one or more control processors at the base station or Constitute a part of the function of the storage element, and may be time-divided.   The output of transmit power controller 328 is sent to summer 336, where Its output is summed with the output from the other transmit power control circuits. these Output from the transmission power controller 328 at the same frequency and in the same direction. To be transmitted to other user terminals 124 and 126 as an output of . The output of the adder 336 is an appropriate FR carrier for digital-to-analog conversion. For converting to frequency, for amplification, for filtering, and for user terminals 124 , 126 to radiate to one or more antennas 340 for analysis To the transmitter 338. Antennas 310 and 340 are complex A similar antenna depending on the size and configuration may be used.   To implement an embodiment of the present invention, one or more pre-compensators or frequencies In addition, preliminary timing correction elements 342 and 344 are used. Preferably, spare Correction element 342 is a digital power controller 32 at baseband frequency. 8 is used to adjust the frequency of the digital output. In the user terminal In other words, baseband spectrum information including frequency adjustment is transmitted to the analog transmitter 338. Is adjusted to the appropriate center frequency during the up-conversion performed in this case. This frequency Pre-conversion is achieved using known techniques such as complex signal rotation described above. You. Here, the known satellite ephemrides and the desired channel The rotation angle is calculated based on the frequency. At the user terminal, other signal Transfer technology and related hardware are well known in the art. Things.   In FIG. 3, the pre-corrector 342 is depicted in the transmission path prior to the summer 336. Have been. This is a separate control for each user terminal signal on request Is allowed. However, after the summer 336, a preliminary correction is made. In this case, a signal frequency preliminary correction element can be used. Because, user term Null protects the same transmission path from the gateway Because it is divided into stars.   As an alternative, the frequency / timing of the signal coming out using well-known techniques The pre-corrector 334 is used to adjust the transmission path on the output of the analog transmitter 338. Can be placed inside. However, change the frequency on the output of the analog transmitter Doing so may be more difficult and lead to interference in the signal filtering process Absent. As a modification, the output frequency of the analog transmitter 338 is usually the center frequency. Control Pro to provide a shifted output frequency offset from the number It can be adjusted directly by the processor 320.   In the above discussion of the user terminal 200, the pre-correction element 34 2, 344 are known pre-correction circuits that can form part of such an element. Use in the transmission path to adjust the timing of outgoing signals. Can be. In addition, it helps to make timing changes as needed The use of similar preliminary time correction elements in addition to the preliminary correction elements 342 and 344 Can be. Preliminary timing correction is based on relative signal timing or PN code Can be used with or without the frequency preliminary correction.   However, the timing adjustment is based on the fact that the signal is baseband and the power Control processor adjustment command when generated prior to output by the controller. Mode generator and timing or other signal parameter timing Is generally realized by The controller 320 is a power controller. As when signals were transmitted to various satellites and user terminals, for example, Code timing and code application.   Outgoing user terminal signals and signals appearing on the forward link and / or The amount of timing correction is determined by the knowledge between the gateway and each satellite with which communication is established. It is based on Doppler. Need to consider satellite Doppler The shift amount is known by using the satellite orbit position data and the control processor. 320. This de The data is stored and stored in one or more storage elements 346, such as a look-up table or the like. Or from the memory element. This data may also include other data as needed. Can be provided from sources. RAM and ROM circuits or magnetic storage devices Use of various known elements to constitute the storage element 346 Can be. This information is always available for the satellites used by the gateway. Used to establish the wave number or timing adjustment.   As shown in FIG. 3, a time and frequency unit (TFU) 348 is an analog receiver. A reference frequency signal is provided for the transceiver 314. Universal from GPS receiver Time (UT) signal is used as part of this process in some applications Can be If necessary, this can be used in the multi-intermediate conversion process. Wear. As shown, TFU 348 serves as a reference for analog transmitter 338 It will be. TFU 348 also includes digital receivers 316A-N and 318. Correlator or Transmit Modulator 326 and Control Processor 3 at 20 or another stage or processor in the gateway. The TFU 348 provides a timing signal to the sing element. TFU 348 If necessary, the relative clock of the (clock) signal is controlled by a predetermined amount under processor control. It is configured to advance and delay the imming.   At least the gateway processor 3320 controls the reception module 324 and the transmission module. Module 334 and the baseband circuit 322. These units May be physically separated from each other. The control processor 320 , Command and control signals to provide signal processing, timing signal generator, Power control, handoff control, divers connection and system interface A function like (but not limited to). In addition to this, The role processor 320 includes a PN extension code, an orthogonal code sequence, and a user Assigned to a particular transmitter and receiver or module for use in communications.   The control processor 320 also provides pilot, synchronization, and page signal generation. Control the coupling and power to the transmission power controller 328 I do. A pilot channel is simply a signal that is not modulated with data, A repetition invariant pattern or a non-changing frame so as to transmit the modulator 326 Structured form inputs may be used. That is, a channel for the pilot signal is formed. The orthogonal function, Walsh code, used to perform Well-known countermeasures such as having a constant value or a spaced 1 and 0 structure pattern It generally has a reverse pattern. Thus, given by the PN generators 332,332 The preferred result is that only the PNT spreading code is transmitted.   The control processing device 320 includes a transmission module 334 or a receiver module. Module 324, can be directly coupled to the module components. Also, each module , A module such as the transmission control processor 330 or the receiver control processor 321. Generally has a control processor of the module specification, and the processor Control. Thus, in a preferred embodiment, the control processor 32 0 is coupled to the transmission processor 330 and the receiver processor 321 as shown in FIG. Have been. In this way, a single control processor 320 may Operation and resources can be controlled relatively effectively. The transmission control device 330 The generation of pilot, synchronization, and page and transmission channel signals and their For controlling the signal power and also the respective coupling to the power controller . The receiver control unit 321 is provided for demodulating and monitoring received power. Control the PN spreading code.   For certain operations, such as shared resource power control, the gateway 120 , 122 are the user's side of the received signal strength, frequency measurement, or communication signal. Receive information such as other received signal parameters from the terminal. This information is Obtained from the demodulated output of the data receiver 316 by the You. Alternatively, this information may be stored in control processor 320 or receiver processor 32. 1 when the signal is monitored and transmitted to the control processor 320 by a preset Can be detected as it occurs in The control processing device 320 includes a transmission power controller. Signals transmitted and processed using the analog transmitter 338 and the analog transmitter 338. No This information (described below) is used to control the timing and frequency. You.   While the communication system 100 is operating, a communication signal referred to as a forward link signal s (t) is calculated by gateways 120 and 122 to A₀Gateway generation and transport around The wave number is transmitted to terminals 124 and 126 on the user side. The forward direction Link signals are subject to time delays, propagation delays, and frequency displacements due to Doppler and other effects. experience. The forward link signal can help address the transition from gateway to satellite. Experience these effects (ie, in the uplink portion of the forward link signal), and The effect is also experienced during the transition from the star to the user-assessed terminal (ie, forward In the downlink part of the link signal). When a signal is received, return or reverse Link transmission delay, propagation delay, and (In the uplink part of the reverse link signal) Doppler at the transition (ie, at the link section of the reverse link signal) I have.   FIG. 4 shows various signals transmitted in the communication system 100. Gateway 1 20 is to transmit the forward link signal 410 to the user terminal via the satellite repeater 116. Is transmitted to the null 124. This forward link signal 410 is transmitted by the gateway 120 Unlink part 412 from the satellite repeater 116 to the user And a downlink section to the terminal 124 on the side. Terminator on the user side The null 124 transmits the reverse link signal 420 via the satellite repeater 116 to the gateway. The data is transmitted to the agent 120. The reverse link signal 420 is transmitted from the user terminal Uplink section 422 from the base station 124 to the satellite intermediate device 116 and the satellite repeater 116 And a downlink section to the gateway 120.   Gateway 120 transmits forward link signal 410 to satellite repeater 116 Sometimes, the uplink unit 412 establishes a connection between the gateway 120 and the satellite repeater 116. As a result of the relative movement between (i.e., as satellite transponder 116 moves), the frequency Experience Doppler or Code Doppler. As is well known, satellite relay As unit 116 approaches gateway 120, uplink section 412 becomes , Code or PAL of the PN code sequence as a result of Code Doppler S You will also experience a decrease in width. The opposite effect is that satellite repeater 116 This occurs in the uplink section 412 as the distance from the terminal 120 increases.   Similarly, the satellite transponder 116 transmits a forward link signal to the terminal 124 on the user side. When transmitting 410, the downlink section 414 communicates with the satellite repeater 116 and the user. Relative movement between the terminal 124 on the side (ie, the satellite transponder 116 and the user). As both the terminal 124 on the side move) and the frequency Doppler and Experience with Code Doppler. As is well known, the satellite transponder 116 As the user approaches the terminal 124 on the user side, the gun link unit 414 becomes As a result of frequency Doppler, it experiences an increase in its carrier frequency. Also, The Unlink Doppler 414 has its PN code as a result of Code Doppler. Experience a decrease in the code or pulse width of the code sequence. The opposite effect is Down as the satellite transponder 116 moves away from the terminal 124 on the user side. Link portion 414.   The Doppler effect at the carrier frequency will be described with reference to FIG. Fig. 5 If the satellite transponder 116 is a gateway 120 and a user terminal 124, Doppler effect at the carrier frequency of the forward link signal 410 as it approaches Is shown. Carrier frequency 510 (f_carrier510) with the forward link signal 41 0 is transmitted from the gateway 120. Uplink unit 412 is up Link Doppler frequency 520 (f_uplink520) as shown in FIG. With the puller, you experience an increase in the carrier frequency. Thus, the order in the satellite repeater The frequency (f_SAT) Is the uplink with carrier frequency 510 It is obtained by adding the Doppler frequency 520. The downlink section 414 is Unlink Doppler frequency (f_downlink530) as shown in FIG. Due to the puller, you will experience an increase at that frequency. Thus, the user's terminal Le 124 (f_UTThe frequency of the forward link signal 410 in FIG. , Uplink Doppler frequency 520 and downlink Doppler frequency 53 0 is added.   The uplink Doppler frequency 520 and the downlink Doppler frequency 53 0 changes according to the relative movement of the satellite transponder 116, so that the user side The frequency of the forward link signal 410 at terminal 124 also changes. This change Is called frequency uncertainty. Communication system 100 using LED satellite The frequency uncertainty is in the range 50 to 300 kHz or That is all.   FIG. 6 shows an example of a frequency pre-correction process performed according to an embodiment of the present invention. You. The forward link signal 410 has a carrier frequency 510 (f_carricr 510). Before being transmitted from the gateway 12, the forward link signal 4 10 is calculated by the pre-corrector 342 using the pre-correction frequency and the pre-correction factor 610. Is adjusted. The frequency pre-corrector 610 has a large up-doppler frequency 520. The magnitudes are equal but the signs are opposite. Thus, the forward link signal 410 is gated. When transmitted from way 12, forward link signal 410 includes carrier frequency 510 and , And the pre-correction frequency 610 added thereto. Soshi Thus, the uplink section 412 of the forward link signal 410 Experiencing a change in frequency at frequency 520. In the present invention, the satellite repeater The frequency of the forward link signal 410 at 116 (f_SAT) Is the carrier frequency 510 , The sum of the pre-correction frequency 610 and the uplink Doppler frequency 520 You. The pre-correction frequency 610 and the uplink Doppler frequency 520 are large Are the same and the signs are opposite, the forward link signal 410 The frequency is equal to the carrier frequency 510.   Downlink section 414 also has its downlink Doppler frequency 530. At the frequency of However, according to the invention, the user terminal 12 4, the frequency (fUT) of the forward link signal 410 is the carrier frequency 510 And the downlink Doppler frequency 530. User terminal 124 At a downlink Doppler frequency of 5 30 changes from this carrier frequency 510. Therefore, the present invention The frequency is simply the downlink Doppler frequency 530 with uncertain consequences It is obtained. For practical purposes, the invention relates to a satellite repeater 11 6 in half for the interrelated user terminal 124 Therefore, the uncertainty of the frequency is reduced.     FIG. 7 illustrates a forward link of a gateway 120 according to one embodiment of the present invention. 4 shows steps for pre-correcting the frequency for the lock signal 410. Step In step 710, the transmitter 338 transmits one or more satellite repeaters 116 Prepare a frequency for the forward link signal 410 to be transmitted to Step 7 At 20, the control processor 320 transmits the forward link signal 410 to be transmitted. The associated movements and corresponding attributes are sent to each satellite repeater 116. Calculate the uplink Doppler frequency 520. In the next step 730, Collector 342 is pre-corrected by its uplink Doppler frequency 520. Pre-modify the forward link signal 410 with the corrected carrier frequency 510 or to correct. Finally, in step 740, transmitter 338 determines the carrier frequency 510 on the uplink Doppler frequency 5 20.   Other embodiments of the present invention may similarly operate in reverse link signal 420. I will do it. In this embodiment, the user terminal 124 has its satellite repeater Data 116 does not have knowledge of the associated movement. Therefore, user terminal 1 24, one different to determine the uplink Doppler frequency signal 520. Technology must be used. The user terminal 124 knows this Based on carrier frequency 510 and frequency of forward link signal 410 are doing. The difference between these frequencies is determined by the downlink Doppler frequency signal 53. 0. Receives forward link signal 410 and transmits reverse link signal 510 Between the user terminals 124, there is a noticeable relative movement as a satellite. No significant change, the downlink Doppler frequency signal of the forward link signal 410 530 is the uplink Doppler frequency signal 520 of the reverse link signal 410 Is assumed to be approximately equal to For more information on this technology, see Patent Serial Number No. 08 / 723,724 “Determination Of Frequency Offsets In Commun ication Systems ”.   FIG. 8 illustrates one reverse link signal 420 from user terminal 124. The step of correcting the frequency in advance is shown. In step 810, the sending Transmitter 230 is the reverse to be transmitted to one or more satellite repeaters 116. Prepare the directional link signal 420. In step 820, the control processor 220 Is the known carrier frequency 510 and the recently received forward link signal 4 Calculate downlink Doppler frequency 530 based on 10. These two The frequency difference is determined by the downlink Doppler frequency signal 5 of the forward link signal 410. 30. And this is the uplink Doppler for the reverse link signal 420 -Approximation to frequency 530. In the next step 830, the pre-collector 232 is the reverse link signal 4 due to its uplink Doppler frequency 530 20 is modified or corrected in advance. Finally, at step 840, the transmitter 2 30 uplinks the reverse link signal 420 on the carrier frequency 510 Transmit at the carrier frequency modified by the Doppler frequency 520.   Another embodiment of the present invention relates to the location and dynamics of the user terminal 124. It is based on the knowledge of If the position of the user terminal 124 or dynamic If the position is known, for example, the position of the device at the user terminal 124 is determined. The uplink Doppler frequency 520 and the downlink Both the puller frequency signal 530 is calculated and corrected for their effect. In fact, if both of these Doppler frequencies are known, the signal is It can be used for corrections and for quick corrections. In both cases, its frequency Is the uncertainty associated with the signal and is removed as fictitious.   Another issue with transmitting signals through satellites is that they are close to the transmitter. The change (deviation) in the propagation delay for a satellite in position, eg, one For satellites located far away from the gateway location and transmitter. This change (deviation) manifests itself as timing uncertainty. In FIG. Uncertain timing for forward link signal 910 and reverse link signal 920 Is shown. As shown in FIG. 9, the forward link signal 910 is actually two different signals. And one forward link signal 910A transmits one farthest satellite 930. To the user terminal 124 and the forward link signal 910B It is to be transmitted to the user terminal 124 via the nearby satellite 940. . The purpose of this description is to make the forward link signal 910A and the forward link The difference from the link signal 910B is the same. The difference between those signals is The tow 120 detects this and separates the satellite. Also in FIG. Shows two user terminals 124 at different locations, which are illustrated in the figure. This is for easy understanding. The purpose described in FIG. The terminal 124 is physically the same. Or forward phosphorus Signal 910A and the forward link signal 910B are different satellites 930, 9 Even if it goes through 40, it reaches the same user terminal 124. The forward link signal 910A has one uplink section 912A and the downlink section 912A. Section 914A. Similarly, the forward link signal 910B is one up It includes a link unit 912B and a downlink unit 914B.   FIG. 9 also shows the reverse link signal 920 as two signals. Reverse The direction link signal 920A is transmitted via one farthest satellite 930 to the gateway. And the reverse link signal 920B is transmitted to the latest satellite 94 0 to the gateway 120. The reverse link signal 920A is It includes one uplink section 922A and one downlink section 924A. As well And the reverse link signal 920B includes one uplink section 922B and one The downlink section 924B is included.   Due to the difference in the distance between gateway 120 and satellites 930, 940 , The forward link signals 910A, 910B are consequently at different times. The terminal 124 is reached. As shown in FIG. 9, the forward link signal 910A is , Forward link signal 910B arrives at user terminal 124 at time 950 In the meantime, the user terminal 124 is reached at time 960. The difference between these times is Corresponding to the expected time range that will arrive at the user terminal 124 It is. In other words, the forward link signal 910 is generated at time 950 and time 960. Can be said to reach the user terminal 124 within the range of. This range is usually Appears as uncertainty in imming. In response to the forward link signal 910, The uncertainty of the imaging is as its user terminal (UT) forward uncertainty Referenced.   FIG. 9 also shows uncertain timing for the reverse link signal 920. You. The reverse link signal 920A is the gateway 1 While reaching the time 970 at 20, the gateway 120 reaches the time 980.   The difference between these times determines the range of times that will reach that gateway 120. It represents. The uncertainty of this timing at times 970 and 980 is (GW) inverse It is referred to as directional timing uncertainty. One using LEO satellite In the communication system 100, this timing uncertainty Approximately 10 to 20 ms, or the satellite communication The uncertainty of the mining is more than the timing uncertainty of about 1-2 ms It is.   As mentioned above, the timing uncertainty can be attributed to the separated spectrum communication signal. The receiver must search the full range of its timing. No. This is the characteristic tuning of the system and the PN code sequence Use The present invention is based on the difference in the distance between the transmitter and the satellite. Transmitting communication signals at different timings This reduces the certainty, so that the given communication signal is the same regardless of distance. Sent to reach all satellites.   FIG. 10 illustrates the forward link signal 910 and the reverse link signal according to one embodiment of the present invention. The timing uncertain period for the slink signal 920 is shown. According to the present invention, The forward link signal 910A is the most Sent to user terminal 124 via distant satellite 930. Forward link signal 910B is communicated to gateway 120 via satellite 940 closest to time 1020. Is transmitted to the user terminal 124. The difference between time 1010 and time 1020 is , Pre-correction time, or more specifically, the forward link pre-correction time. The forward link pre-correction time is based on the distance and the gateway receiving the signal with the gateway 120. Determined based on the associated propagation delay with the star, the signal is the same regardless of distance Arrive on satellite at time. For example, the forward link signal 910A is the farthest satellite At 930, the forward link signal 910B is simultaneously sent to the nearest satellite 940 at time 1 030 (referred to as satellite time 1030).   Each satellite 930, 940 couples forward link signal 910 to user terminal 124. And repeat. The forward link signal 910A is transmitted to the user terminal 12 at time 1050. Arriving at 4. Forward link signal 910B is transmitted to user terminal 12 at time 1040. Arriving at 4. The difference between time 1050 and time 1040 is the user terminal of the present invention. Represents the forward timing uncertainty period. The present invention provides a forward link signal 91. User terminal by the amount of the timing uncertainty period associated with the uplink section 912 of zero The forward timing uncertainty period is reduced. This is the forward link signal 91 This is because 0 indicates that satellites 930 and 940 arrive at satellite time 1030. .   FIG. 10 shows the worst uncertainty period based on the farthest satellite 930 and the closest 940 are doing. The above discussion is based on the transmit forward link for one or more satellites. 910 is assumed, but is not limited to this. For example, only one satellite May be within the line of sight of a particular gateway 120. In this case the gateway Way 120 can only transmit to one satellite. As another example, certain communication systems 100 is not performing diversity processing and disables multiplexing of the same signal. I will. Regardless of the number of satellites used, the present invention pre-corrects the timing of signal transmission This reduces the timing uncertainty period in the received signal, The signal arrives at the satellite at a known time.   In one embodiment of the present invention, the start of signal transmission is not only pre-corrected, but also Are continuously pre-corrected, so that each component of the signal (ie, the PN code) Arrive on satellite at time. Embodiments of the present invention reduce the timing uncertainty period. And Doppler compensation. As with the frequency pre-correction described above, Is known or corrected on the satellite, so the code Doppler is The pre-correction is performed only on the uplink section 912 of the uplink signal. This allows code The uncertainty period due to the time is reduced and the work of the time tracking loop is much easier.   FIG. 11 illustrates a forward link signal 910 and a reverse link signal according to another embodiment of the present invention. 7 shows a timing uncertain period for the uplink signal 920. The present invention According to an embodiment of the present invention, the forward link signal 910 may be configured as described above with respect to FIG. Transmitted by the gateway 120 in the same manner as the gateway. This embodiment is A method similar to the method related to the reverse link signal 920 is used. User terminal 124 Reverses to gateway 120 via the furthest satellite 930 at time 1110 The link signal 920A is transmitted. User terminal 124 is the satellite closest to time 1120 A reverse link signal 920B is transmitted to the gateway 120 via 940. The difference between time 1110 and time 1120 is called the reverse link pre-processing time . Since the user terminal 124 does not know its position, the user terminal 124 1030 and the time when the forward link signal 910 arrives at the user terminal 124. The reverse link pre-correction time is determined based on the time difference between. This time difference is It corresponds to the propagation delay of the downlink section 914 of the forward link signal 910. Pho The overall transition between receiving the word link signal 910 and transmitting the reverse link signal 920 Assuming that there is almost no movement, the propagation delay of This is the same as the propagation delay of the uplink section 922 of the link signal 920, which is required. This is the required pre-reverse link correction time.   The reverse link pre-processing time adjusts the transmission of the reverse link signal 920 or Compensation, whereby the reverse link signal 920 is Arrives at the satellite at a known time, called zero. The satellite transmits the reverse link signal 920 Repeat for user terminal 124. Reverse link signal 920A is at time 115 At 0, the user terminal 124 arrives. The difference between time 1150 and time 1140 is 3 shows a gateway reverse timing indefinite period of the invention. Embodiments of the present invention Gate Fail reverser as well as user terminal forward timing uncertainty period Also reduces the imming uncertainty period. For the forward link 910, the user The terminal forward timing uncertainty period corresponds to the timing related to the uplink section 912. Is reduced by the amount of the uncertainty period. Gate for reverse link 920 The way reverse timing uncertain period is the time related to the uplink section 922. Is reduced by the ringing uncertainty period.   FIG. 12 illustrates a forward link at gateway 120 according to one embodiment of the present invention. Shown are steps performed to pre-correct the timing for signal 910. At step 1210, the control processor 320 communicates with the gateway 120 The distance between each of the satellites 930 and 940 to which the link signal 910 is transmitted is calculated. Next, at step 1220, control processor 320 determines based on each of these distances. Calculate the propagation delay.   Such a distance may be, for example, immediately or after a known delay, from the satellite to the user. Measure the round trip delay of the signal sent to the terminal, divide the result by 2, and add the signal to the result Obtained by multiplying the speed of (light). The round-trip delay is the known running P Transmit a signal containing an N sequence or a spreading code, and By comparing the state of the PN sequence of the retransmission signal when received by the Measured. State difference is the total round-trip delay (known delay from gateway to satellite) ). Known delay uses known satellite ephemeris And is calculated by various methods well known in the art. On the other hand, the distance is one Using the round trip delay of the signal transmitted through one satellite and returned through the second satellite Measured. However, more information about the relative position is required. This It is generally provided using other signal parameters. Such a method is This is described in more detail in the co-pending patent application mentioned above with respect to the definition.   At step 1230, the pre-corrector 342 determines the propagation for each satellite 930, 940. Preprocess or compensate the forward link signal 410 to indicate the delay. last In step 1240, the transmitter 338 sends the satellites 930, 94 with appropriate timing. The forward link signal 410 pre-corrected for 0 is transmitted.   FIG. 13 illustrates a reverse link signal at a user terminal 124 according to one embodiment of the present invention. 9 shows the steps performed to pre-correct the timing for 920. S At step 1310, the control processor 220 transmits the reverse link signal 920. The most recently received forward link signal from each of the satellites 930 and 940 to be transmitted. The propagation delay is calculated based on the number 910. In step 1320, the pre-corrector 232 , Reverse link signal 92 to indicate the propagation delay for each satellite 930, 940. 0 is pre-corrected or compensated. Finally, at step 1330, the transmitter 230 Reverse link signal 92 pre-corrected for satellites 930 and 940 whose Send 0.   The timing uncertainty period, i.e., the search space of the receiver for acquiring a signal is reduced. In addition to reduction, the present invention provides a communication system 100 employing diversity processing. Reduce the amount of deskew memory buffer required by This type of system The system uses a timing uncertainty period to receive signals from all possible paths. The incoming signal must be buffered over the entire range. Timing uncertainty period (Ie, the time at which signals from all possible paths are expected) Therefore, the deskew memory is correspondingly reduced.   A preferred embodiment of the present invention provides a pre-corrector that performs frequency and timing pre-correction. Have. As described above, frequency pre-correction and timing pre-correction The confirmation period is reduced by about 1/2. That is, the preferred embodiment of the present invention The search space of the receiver can be reduced to about 1/4 of the search space. sand That is, in one embodiment of the present invention, the gateway 120 and the user terminal 124 , About 1/4 of the time or about 1/4 of the receiver compared to the corresponding device The signal can be obtained by the number of.   The preferred embodiments described above are intended to enable one of ordinary skill in the art to make or use the invention. Offered to. Various modifications to these embodiments are readily available to those skilled in the art. Function, and the general principles specified here may be used without using new capabilities. This is also applied to the embodiment. That is, the present invention is limited to the embodiments disclosed herein. It is not intended to be limited, but is consistent with the principles and novel features disclosed herein. Should be given a wide range of rights.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (GH, KE, LS, MW, S D, SZ, UG, ZW), EA (AM, AZ, BY, KG) , KZ, MD, RU, TJ, TM), AL, AM, AT , AU, AZ, BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, ES, F I, GB, GE, GH, HU, ID, IL, IS, JP , KE, KG, KP, KR, KZ, LC, LK, LR, LS, LT, LU, LV, MD, MG, MK, MN, M W, MX, NO, NZ, PL, PT, RO, RU, SD , SE, SG, SI, SK, SL, TJ, TM, TR, TT, UA, UG, UZ, VN, YU, ZW

Claims (1)

[Claims] 1. A method for transmitting a signal in a communication system using satellites, the method comprising receiving Doppler signals. To reduce the effect on the transmitter.   The transmission method includes:   Continuously calculating the Doppler frequency of the satellite for the transmitter;   The Doppler frequency so that the signal is received by the satellite without Doppler. Adjusting the transmission frequency of the signal as a function of a number;   With   The satellite receives a signal from the transmitter, and the satellite transmits a signal to the receiver. A method of transmitting repetitive signals. 2. A method for transmitting a signal in a communication system using satellites, the method comprising: Reduce the effect of Doppler   The transmission method includes:   Continuously calculating the distance between the satellite and the transmitter;   Determining the propagation time required for the signal to traverse the calculated distance When,   Subtract the propagation time from a predetermined time to obtain a corrected transmission timing Calculating,   Compensating the signal so that the signal is received by the satellite at the predetermined time. Transmitting at the corrected transmission timing;   With   A method for transmitting a signal, wherein the satellite receives the signal from the transmitter.