• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    There is provided a channel estimating apparatus and method in a radio communication system. In the channel estimating apparatus, a fading estimator estimates a channel using preset symbols of an input signal, a first interpolator interpolates the other symbols of the input signal based on the fading estimation, a first inverter inverts the output signal of the first interpolator, a first delay delays the input signal for a predetermined time, a first multiplier primarily compensates the output signal of the first delay by means of the output signal of the first inverter, a second interpolator interpolates each symbol of the input signal relating to primarily compensated symbols in a predetermined period before and after the symbol, a level controller controls the level of the output signal of the second interpolator, a second inverter inverts the output signal of the level controller, a second delay for delays the primarily compensated signal for a predetermined time, and a second multiplier secondarily compensates the output signal of the second delay by means of the output signal of the second inverter.
    公开号:US20010006540A1
    申请号:US09/737,406
    申请日:2000-12-15
    公开日:2001-07-05
    发明作者:Kyu-Hak Kim;Je-woo Kim;Hyung-Suk Kim;Ki-Soo Kim
    申请人:Samsung Electronics Co Ltd;
    IPC主号:H04L25-0214
    专利说明:
    [0001] This application claims priority to an application entitled “Apparatus and Method for Channel Estimation in Radio Communication System” filed in the Korean Industrial Property Office on Dec. 29, 1999 and assigned Ser. No. 99-65273, the contents of which are hereby incorporated by reference. [0001] BACKGROUND OF THE INVENTION
    [0002] 1. Field of the Invention [0002]
    [0003] The present invention relates generally to data demodulation in a radio communication system, and in particular, to an apparatus and method for demodulating data against signal distortion caused by fading or other factors. [0003]
    [0004] 2. Description of the Related Art [0004]
    [0005] Radio communication technology, mainly cellular communication technology has been rapidly developed and GMPCS (Global Mobile Personal Communication System) is being deployed for communication throughout the world. For radio communication systems utilizing satellites, research has actively been conducted on data demodulation because the long distance between a satellite and a mobile station causes severe data distortion due to fading. [0005]
    [0006] In general, predetermined symbols (e.g., pilot symbols) are inserted in one frame prior to transmission and the distortion of other information symbols are compensated for by detecting the distortion of the predetermined symbols. That is, a transmitter inserts agreed symbols between data symbols prior to transmission and a receiver extracts those agreed symbols for use in channel estimation. Conventional channel estimation relies on the use of an interpolator or extended symbol-aided estimation (ESAE). [0006]
    [0007] With respect to prior art systems, FIG. 1 is a schematic block diagram of a conventional channel estimating apparatus in a radio communication system for data recovery. FIG. 2 is the format of a frame used in the conventional radio communication system. FIG. 3 is a detailed block diagram of the conventional channel estimating apparatus in the radio communication system. FIG. 4 is a block diagram of another conventional channel estimating apparatus relying on ESAE in a radio communication system and FIG. 5 conceptually illustrates channel estimation for data recovery relying on the ESAE. [0007]
    [0008] FIG. 1 illustrates a channel estimating apparatus using pilot symbols for channel estimation in a PSAM (Pilot Symbol Assisted Modulation) system. In the PSAM system, pilot symbols are periodically inserted by pilot symbol inserter [0008] 101 between data symbols and the entire signal is pulse-shaped by pulse shaper 102 prior to transmission. Fading and AWGN (Additive White Gaussian Noise) are added to the transmission signal by multiplier 103 and adder 104, respectively. A receiver separates an input signal into pilot symbols and data symbols by passing the input signal through a matched filter 105 and estimates the channel of data symbols using the pilot symbols. For the channel estimation, an interpolator 108 is required and data is recovered using the interpolation result. Delay 106 compensates for the signal delay through interpolator 108.
    [0009] The channel estimation process in a general PSAM system can be expressed briefly as [0009]
    [0010] where St(t) is the transmitter signal, Re[zO(t)exp(j2πfct)] represents the real number part of zO(t)exp(j2πfct), fc is a carrier frequency, and zO(t) is a transmission baseband signal with its band limited by a transmission filter. As shown in FIG. 2, preset pilot symbols are inserted into a transmission frame. Due to fading, the transmission signal arrives at the receiver as [0010]
    [0011] where Sr(t) is the received signal, and nc(t) is the AWGN component. A channel complex gain c(t) includes fading and a frequency offset, given by [0011]
    [0012] It is necessary to estimate C(t) to achieve the baseband signal Z(t). The sampled value of an m[0012] th symbol in a kth frame is
    [0013] where TP, a pilot symbol insertion period, is NT. A pilot symbol demodulated at every frame timing instant is [0013]
    [0014] An estimated value of fading at the instant when a k[0014] th pilot symbol is received is computed by dividing a distorted symbol U(tk, 0) of Eq. (7) by a pilot symbol b. That is,
    [0015] Fading-caused distortion of an information symbol can be detected using an interpolator as applied to Eq. (8). There are generally two interpolation methods: fixed interpolation and adaptive interpolation. For fixed interpolation, a sync (Nyquist), Gaussian, linear, or a cubic interpolator is applied throughout a channel to estimate the distortion of the channel regardless of channel variation, whereas for adaptive interpolation, for example, a Wiener interpolator using a Wiener filter accurately estimates a channel by adaptively compensating for channel variation utilizing parameters like Doppler frequency and symbol energy per power spectrum density (Es/No). [0015]
    [0016] FIG. 3 is a conceptual view of the fading estimation and compensation using a sync interpolator. As shown in FIG. 3, for channel estimation, a fading estimator [0016] 301 estimates fading of pilot symbols and an interpolator 302 interpolates data symbols based on the channel estimation of the pilot symbols. The channel estimation result is reflected in an input signal delayed by a delay 304, to thereby compensate the input signal.
    [0017] FIGS. 4 and 5 illustrate the other channel estimation scheme, ESAE. A receiver separates an input signal into pilot symbols and data symbols by passing the input signal through a matched filter [0017] 401. For the channel estimation, an interpolator 403 is required and data is recovered using the interpolation result. First delay 402 compensates for the signal delay through interpolator 403. Demodulator 405 demodulates the signal. As shown in FIG. 5, recovered data before a symbol “S” is used along with pilot symbols “P1”, “P2”, “P3”, and “P4” to estimate the channel of the symbol “S”.
    [0018] Despite relative simplicity in channel estimation, the data estimation scheme using pilot symbol channel estimation and the ESAE scheme have shortcomings in that channel estimation is not reliable when a received signal has weak strength or experiences severe fading. [0018] SUMMARY OF THE INVENTION
    [0019] It is, therefore, an object of the present invention to provide a channel estimating apparatus and method capable of channel estimation even in an environment where fading causes severe distortion. [0019]
    [0020] The above object can be achieved by providing a channel estimating apparatus and method in a radio communication system. In the channel estimating apparatus, a fading estimator estimates a channel using preset symbols of an input signal, a first interpolator interpolates the other symbols of the input signal based on the fading estimation, a first inverter inverts the output signal of the first interpolator, a first delay delays the input signal for a predetermined time, a first multiplier primarily compensates the output signal of the first delay by means of the output signal of the first inverter, a second interpolator interpolates each symbol of the input signal relating to primarily compensated symbols in a predetermined period before and after the symbol, a level controller controls the level of the output signal of the second interpolator, a second inverter inverts the output signal of the level controller, a second delay delays the primarily compensated signal for a predetermined time, and a second multiplier secondarily compensates the output signal of the second delay by means of the output signal of the second inverter. [0020] BRIEF DESCRIPTION OF THE DRAWINGS
    [0021] The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings in which: [0021]
    [0022] FIG. 1 is a schematic block diagram of a conventional channel estimating apparatus in a radio communication system; [0022]
    [0023] FIG. 2 is the format of a frame used in the conventional radio communication system; [0023]
    [0024] FIG. 3 is a detailed block diagram of the channel estimating apparatus in the conventional radio communication system; [0024]
    [0025] FIG. 4 is a block diagram of another conventional channel estimating apparatus relying on ESAE in a radio communication system; [0025]
    [0026] FIG. 5 is a conceptual view of channel estimation for data recovery relaying on the ESAE in the radio communication system; [0026]
    [0027] FIG. 6 is a block diagram of a channel estimating apparatus according to an embodiment of the present invention; [0027]
    [0028] FIG. 7 is a conceptual view of channel estimation for data recovery according to the embodiment of the present invention; and [0028]
    [0029] FIGS. 8A to [0029] 8D are graphs showing BER characteristics according to the embodiment of the present invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
    [0030] A preferred embodiment of the present invention will be described herein below with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. [0030]
    [0031] FIG. 6 is a block diagram of a channel estimating apparatus according to an embodiment of the present invention and FIG. 7 is a conceptual view of channel estimation for data recovery according to the embodiment of the present invention. [0031]
    [0032] Referring to FIG. 6, a fading estimator [0032] 600 estimates fading using preset pilot symbols in an input signal. A first interpolator 610 interpolates information symbols based on the fading estimation. A Wiener interpolator may be used as the first interpolator 610. A first inverter 620 obtains the reciprocal number of the output of the first interpolator 610 through inverting. A first delay 630 delays an input signal for a predetermined time to provide action time to the fading estimator 600, the first interpolator 610, and the first inverter 620. A multiplier 640 primarily compensates the delayed signal received from the first delay 630 using the channel estimation signal inverted by the first inverter 620. The primary compensated signal is fed to a second interpolator 650 and a second delay 680. The second interpolator 650 is preferably a sync or Nyquist interpolator and estimates fading relating to the primarily compensated data as shown in FIG. 7.
    [0033] In FIG. 7, the second interpolator [0033] 650 estimates fading relating to the primarily compensated symbols (marked with slash lines) preceding and following a data symbol S to be estimated. Pilot symbols P1, P2, P3, and P4 that were used for the primary compensation may be used along with the primarily compensated symbols for the secondary channel estimation. The same weight or different weights can be given to the primarily compensated data symbols and the pilot symbols.
    [0034] Referring again to FIG. 6, a level controller [0034] 660 controls the level of the estimated value. For example, if reference symbols are (1, 0) and (−1, 0), all symbols are shifted to a (1, 0) domain by generalizing the other quadrature phase-shift keying (QPSK) symbols (0, 1) and (0, −1), for achieving the channel estimated value. A second inverter 670 inverts the level-controlled signal and a multiplier 690 secondarily compensates the delayed signal received from the second delay 680 by multiplying the delayed signal by the inverted signal received from the second inverter 670.
    [0035] In accordance with the embodiment of the present invention, the channel of the symbol S is estimated through the primary estimation using pilot symbols and the secondary estimation using symbols compensated for by the Wiener interpolator [0035] 610 as new pilot symbols using the Nyquist interpolator 650.
    [0036] While the Wiener interpolator [0036] 610 is used for the primary channel estimation, the Nyquist interpolator 650 is used for the secondary channel estimation because the primarily compensated symbols related thereto are located near the symbol to be estimated.
    [0037] According to the channel estimation method in the embodiment of the present invention, data symbols are more accurately channel-estimated as signal to noise ratio (SNR) increases and use of compensated data symbols along with the pilot symbols increases channel estimation reliability. [0037]
    [0038] FIGS. 8A to [0038] 8D illustrate BER characteristics according to the embodiment of the present invention. The horizontal axis of each of FIGS. 8A to 8D represents Es/No and the vertical axis represents BER variations. Table 1 lists experimental data. TABLE 1 Figure K fd8A 7 dB 20 Hz 8B 7 dB 200 Hz 8C 12 dB 20 Hz 8D 12 dB 200 Hz
    [0039] As noted from FIGS. 8A to [0039] 8D, performance is improved in the embodiment of the present invention, as compared to performance in a conventional Wiener interpolator using scheme.
    [0040] In Table 1, K denotes a Ricean fading factor and fd is a Doppler frequency. Normalized Doppler frequencies (fdT) are 0.0011 and 0.011, that is, 20 Hz and 200Hz in the case where a symbol rate is 18,000 symbols per second. Here, a pilot insertion period M is 20. In the case of coherent demodulation, it is assumed that a receiver accurately knows required Doppler frequency and symbol energy per power spectrum density (γ=Es/No). It is concluded from simulation results that the embodiment of the present invention is superior to the conventional Wiener interpolator using scheme in case of fast fading (fdT=0.011), as shown in FIGS. 8B and 8D. [0040]
    [0041] According to the present invention as described above, a channel is primarily estimated using pilot symbols and secondarily estimated using the primarily compensated symbols. Therefore, channel estimation can be performed even at severe distortion caused by fading. [0041]
    [0042] While the invention has been shown and described with reference to a certain preferred embodiment thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. [0042]
    权利要求:
    Claims (12)
    [1" id="US-20010006540-A1-CLM-00001] 1. A channel estimating apparatus in a radio communication system, comprising:
    a fading estimator for estimating a channel using preset symbols of an input signal;
    a first interpolator for interpolating other symbols of the input signal based on the fading estimation;
    a first inverter for inverting an output signal of the first interpolator;
    a first delay for delaying the input signal for a predetermined time;
    a first multiplier for primarily compensating an output signal of the first delay by means of the output signal of the first inverter;
    a second interpolator for interpolating each symbol of the input signal relating to primarily compensated symbols in a predetermined period before and after the symbol;
    a level controller for controlling the level of an output signal of the second interpolator;
    a second inverter for inverting an output signal of the level controller;
    a second delay for delaying the primarily compensated signal for a predetermined time; and
    a second multiplier for secondarily compensating an output signal of the second delay by means of the output signal of the second inverter.
    [2" id="US-20010006540-A1-CLM-00002] 2. The channel estimating apparatus of
    claim 1 , wherein the first interpolator is a Wiener interpolator.
    [3" id="US-20010006540-A1-CLM-00003] 3. The channel estimating apparatus of
    claim 1 , wherein the second interpolator is one of a sync interpolator and a Nyquist interpolator.
    [4" id="US-20010006540-A1-CLM-00004] 4. The channel estimating apparatus of
    claim 2 , wherein the second interpolator is one of a sync interpolator and a Nyquist interpolator.
    [5" id="US-20010006540-A1-CLM-00005] 5. The channel estimating apparatus of
    claim 1 , wherein the preset symbols are pilot symbols.
    [6" id="US-20010006540-A1-CLM-00006] 6. The channel estimating apparatus of
    claim 4 , wherein the preset symbols are pilot symbols.
    [7" id="US-20010006540-A1-CLM-00007] 7. A channel estimating method in a radio communication system, comprising the steps of:
    primarily compensating other symbols of an input signal using preset symbols; and
    secondarily compensating each symbol of the input signal relating to the primarily compensated symbols in a predetermined period before and after each symbol.
    [8" id="US-20010006540-A1-CLM-00008] 8. The channel estimating method of
    claim 7 , wherein the primarily compensating step comprises the steps of:
    estimating a channel using the preset symbols;
    interpolating the other symbols of the input signal based on the channel estimation and inverting the interpolated signal; and
    compensating the input signal by means of the inverted signal.
    [9" id="US-20010006540-A1-CLM-00009] 9. The channel estimating method of
    claim 7 , wherein the secondarily compensating step comprises the steps of:
    interpolating each symbol relating to the primarily compensated symbols in the predetermined period before and after the symbol and controlling the level of the interpolated symbols; and
    inverting the level-controlled signal and secondarily compensating the primarily compensated signal.
    [10" id="US-20010006540-A1-CLM-00010] 10. The channel estimating method of
    claim 8 , wherein the secondarily compensating step comprises the steps of:
    interpolating each symbol relating to the primarily compensated symbols in the predetermined period before and after the symbol and controlling the level of the interpolated symbols; and
    inverting the level-controlled signal and secondarily compensating the primarily compensated signal.
    [11" id="US-20010006540-A1-CLM-00011] 11. The channel estimating method of
    claim 7 , wherein the preset symbols are pilot symbols.
    [12" id="US-20010006540-A1-CLM-00012] 12. The channel estimating method of
    claim 8 , wherein the preset symbols are pilot symbols.
    类似技术:
    公开号 | 公开日 | 专利标题
    US6751274B2|2004-06-15|Apparatus and method for channel estimation in radio communication system
    EP0715440B1|2004-06-16|Synchronous detector and synchronizing method for digital communication receiver
    EP0605955B1|2001-01-24|Method and apparatus for compensating multipath fading and simulcast interference in a radio signal
    JP3392877B2|2003-03-31|Method and system for determining signal-to-noise and interference power ratio | in a communication system
    US6219334B1|2001-04-17|Receiving apparatus for receiving orthogonal frequency division multiplexing signal and receiving method thereof
    US5875215A|1999-02-23|Carrier synchronizing unit
    US6314131B1|2001-11-06|Method and system for channel estimation using multi-slot averaged interpolation
    US4873683A|1989-10-10|TDMA radio system employing BPSK synchronization for QPSK signals subject to random phase variation and multipath fading
    EP0430481A2|1991-06-05|Method and apparatus for diversity reception of time-dispersed signals
    EP1303064A2|2003-04-16|System and method for in-service decision-directed signal to noise ratio estimation
    NZ270872A|1997-01-29|Equalising of received digital radio signals
    WO2002032067A1|2002-04-18|Method for automatic frequency control
    CA2345534A1|2000-04-27|Adaptive channel tracking using pilot sequences
    US6842476B2|2005-01-11|Co-channel interference canceller
    EP2234290A2|2010-09-29|Relay station, relay method, receiving station and receiving method
    EP0958666B1|2001-12-05|Compensation of doppler shift in a mobile communication system
    US20050107039A1|2005-05-19|Co-channel interference detector for cellular communications systems
    EP1178639A1|2002-02-06|Transmission gain regulating method and radio device
    WO2002023840A1|2002-03-21|Pilot-assisted channel estimation with pilot interpolation
    JP3472768B2|2003-12-02|Maximum Doppler frequency estimation device and wireless communication device
    Berangi et al.2001|Indirect cochannel interference cancelling
    JP2002271430A|2002-09-20|Frequency offset estimating method and frequency offset estimating device
    Rong et al.2021|Synchronization for VHF Data Exchange System
    KR100413152B1|2003-12-31|Transmitting device and transmitting method
    Naitoh et al.1995|Real-time RLS-MLSE equalizer implementation for application to PDC |
    同族专利:
    公开号 | 公开日
    EP1113633B1|2006-11-29|
    CN1166080C|2004-09-08|
    DE60032109T2|2007-03-08|
    KR20010065396A|2001-07-11|
    US6751274B2|2004-06-15|
    JP2001217882A|2001-08-10|
    DE60032109D1|2007-01-11|
    JP3652247B2|2005-05-25|
    KR100318952B1|2002-01-04|
    EP1113633A2|2001-07-04|
    CN1308417A|2001-08-15|
    EP1113633A3|2004-01-02|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US5809083A|1994-11-23|1998-09-15|At&T Wireless Services, Inc.|Differentially encoded pilot word system and method for wireless transmissions of digital data|
    US5875215A|1995-08-25|1999-02-23|Nec Corporation|Carrier synchronizing unit|
    US5748677A|1996-01-16|1998-05-05|Kumar; Derek D.|Reference signal communication method and system|
    US6085103A|1997-02-19|2000-07-04|Ericsson, Inc.|Compensating for fading in analog AM radio signals|
    US6570935B1|1998-05-28|2003-05-27|Nec Corporation|Method and system for demodulating a receive signal including a pilot signal|
    US6577674B1|1998-09-03|2003-06-10|Samsung Electronics Co, Ltd.|Channel compensator for DS-CDMA receiver|
    US6510190B1|1998-12-17|2003-01-21|Nortel Networks Limited|Method and apparatus for estimating fading distortion of a signal propagating in a communication channel|
    US6519296B1|1999-06-03|2003-02-11|General Electric Company|Variable-interval pilot symbol aided modulation and demodulation|US20030185165A1|2002-02-21|2003-10-02|Ntt Docomo, Inc.|System and method of interference suppression|
    US20050111603A1|2003-09-05|2005-05-26|Alberto Ginesi|Process for providing a pilot aided phase synchronization of carrier|
    US20080165900A1|2007-01-09|2008-07-10|Vassilieva Olga I|Demodulating A Signal Encoded According To ASK Modulation And PSK Modulation|
    US20100285766A1|2007-09-28|2010-11-11|Kenta Okino|Reception device, radio communication terminal, radio base station, and reception method|
    US20170134207A1|2015-11-05|2017-05-11|Mediatek Inc.|Signaling and Feedback Schemes of Time-Vary Channels in High-Efficiency WLAN|
    US10187124B2|2015-10-01|2019-01-22|Mediatek Inc|Beam-change indication for channel estimation enhancement|
    US10200228B2|2015-12-17|2019-02-05|Mediatek Inc.|Interleaver design for dual sub-carrier modulation in WLAN|
    US10211948B2|2015-10-12|2019-02-19|Mediatek Inc.|LDPC tone mapping schemes for dual-sub-carrier modulation in WLAN|
    US10225122B2|2016-02-04|2019-03-05|Mediatek Inc.|Low PAPR dual sub-carrier modulation scheme for BPSK in WLAN|
    US10264580B2|2015-09-07|2019-04-16|Mediatek Inc.|HE SIG B common field formats and indication|
    US10371783B2|2014-08-18|2019-08-06|Mediatek Inc.|Direction finding antenna format|
    US10594462B2|2015-09-28|2020-03-17|Mediatek Inc.|Structured resource allocation signaling|
    US11019559B2|2015-12-09|2021-05-25|Mediatek Inc.|VHT operation information subfield design in WLAN|FR2658016B1|1990-02-06|1994-01-21|Etat Francais Cnet|METHOD FOR BROADCASTING DIGITAL DATA, ESPECIALLY FOR BROADBAND BROADCASTING TO MOBILES, WITH TIME-FREQUENCY INTERLACING AND CONSISTENT DEMODULATION, AND CORRESPONDING RECEIVER.|
    US5414734A|1993-01-06|1995-05-09|Glenayre Electronics, Inc.|Compensation for multi-path interference using pilot symbols|
    JP3342177B2|1994-05-13|2002-11-05|富士通テン株式会社|Multi-level QAM fading compensation method|
    EP0715440B1|1994-06-22|2004-06-16|NTT DoCoMo, Inc.|Synchronous detector and synchronizing method for digital communication receiver|
    JP3462937B2|1994-09-27|2003-11-05|富士通株式会社|Automatic amplitude equalizer|
    US5901185A|1996-04-15|1999-05-04|Ericsson Inc.|Systems and methods for data-augmented, pilot-symbol-assisted radiotelephone communications|
    US5912931A|1996-08-01|1999-06-15|Nextel Communications|Method for multicarrier signal detection and parameter estimation in mobile radio communication channels|
    KR100218671B1|1996-09-16|1999-09-01|정선종|The system of compensating rayleigh fading|
    JP3663562B2|1996-12-20|2005-06-22|富士通株式会社|Interference canceller and channel estimation method|
    JP3441636B2|1997-11-21|2003-09-02|株式会社エヌ・ティ・ティ・ドコモ|Apparatus and method for determining channel estimation value, receiving apparatus, and transmission system|
    US6381290B1|1998-05-15|2002-04-30|Ericsson Inc.|Mobile unit for pilot symbol assisted wireless system and method of improving performance thereof|
    KR100277039B1|1998-12-31|2001-01-15|윤종용|Apparatus and method for estimating channel state of channel receiver in code division multiple access communication system|US6438638B1|2000-07-06|2002-08-20|Onspec Electronic, Inc.|Flashtoaster for reading several types of flash-memory cards with or without a PC|
    US20030012308A1|2001-06-13|2003-01-16|Sampath Hemanth T.|Adaptive channel estimation for wireless systems|
    JP4358686B2|2004-06-17|2009-11-04|富士通株式会社|Fading frequency estimation apparatus and estimation method thereof|
    CN100394826C|2004-09-02|2008-06-11|上海贝尔阿尔卡特股份有限公司|Channel quality interpotation method|
    WO2006106474A2|2005-04-08|2006-10-12|Koninklijke Philips Electronics N.V.|Method and apparatus for estimating channel in mobile communication system|
    US8104034B2|2005-11-30|2012-01-24|Red Hat, Inc.|Purpose domain for in-kernel virtual machine for low overhead startup and low resource usage|
    US8612970B2|2005-11-30|2013-12-17|Red Hat, Inc.|Purpose domain for low overhead virtual machines|
    CN101039288B|2006-03-16|2010-05-12|中国科学院上海微系统与信息技术研究所|Channel estimation method and apparatus for preventing timing deviation in OFDM system|
    US8085873B2|2007-01-02|2011-12-27|Qualcomm, Incorporated|Systems and methods for enhanced channel estimation in wireless communication systems|
    法律状态:
    2000-12-15| AS| Assignment|Owner name: SAMSUNG ELECTRONICS, CO. LTD., KOREA, REPUBLIC OF Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:KIM, KYU-HAK;KIM, JE-WOO;KIM, HYUNG-SUK;AND OTHERS;REEL/FRAME:011378/0310 Effective date: 20001208 |
    2007-09-21| FPAY| Fee payment|Year of fee payment: 4 |
    2012-01-30| REMI| Maintenance fee reminder mailed|
    2012-06-15| LAPS| Lapse for failure to pay maintenance fees|
    2012-07-16| STCH| Information on status: patent discontinuation|Free format text: PATENT EXPIRED DUE TO NONPAYMENT OF MAINTENANCE FEES UNDER 37 CFR 1.362 |
    2012-08-07| FP| Lapsed due to failure to pay maintenance fee|Effective date: 20120615 |
    优先权:
    申请号 | 申请日 | 专利标题
    KR1019990065273A|KR100318952B1|1999-12-29|1999-12-29|Channel estimation apparatus in wireless telecommunication system and method thereof|
    KR1999-65273||1999-12-29||
    KR99-65273||1999-12-29||
    [返回顶部]