USRE39981EExpiredUtility

Packet configuring method and packet receiver

51
Assignee: NEC CORPPriority: Jul 8, 1998Filed: Dec 13, 2005Granted: Jan 1, 2008
Est. expiryJul 8, 2018(expired)· nominal 20-yr term from priority
H04L 2027/003H04L 7/041H04L 25/0212H04L 27/0014H04L 25/0226
51
PatentIndex Score
0
Cited by
12
References
16
Claims

Abstract

A packet receiver is provided that accurately estimates a frequency offset and a channel impulse response even when a transmitted packet is detected with an erroneous timing in a communication mode (typified by the LAN (local Area Network)) where packets are asynchronously transmitted, and thus provides a training sequence which can demodulate the received packet. The training sequence 101 is formed of K sequences 100 - 1 to 100 -K serially connected, each formed of the same N symbols. Even in a channel where a intersymbol interference occurs when such a training sequence is used, a received signal shifted by the time corresponding to N-symbols becomes the signal which is different by a phase difference caused by a frequency offset between the transmitter and the receiver. Thus, even if the head of a packet is detected with an erroneous timing, the frequency offset can be estimated.

Claims

exact text as granted — not AI-modified
1. A method of configuring packets, said packets each including a training portion and a data portion, the method comprising forming said training portion by serially connecting K sequences (where K is an integer of 2 or more), each of said K sequences being formed of N symbols (where N is an integer of 2  1 or more), wherein a phase difference between two neighboring sequences of said K sequences is used for frequency- offset estimation , wherein an auto-correlation function for said sequence of N symbols is in an impulse state. 
     
     
       2. A packet receiver that receives packets, each packet including a training portion and a data portion used to initialize said packet receiver, said training portion being formed by serially connecting K sequences (where K is an integer of 2 or more), each of said K sequences being formed of N symbols (where N is an integer of 2  1 or more), the packet receiver comprising  comprises:
 a frequency-offset estimation means for estimating a frequency offset based on a phase difference between two neighboring sequences of K sequences of a received packet, each of said K sequences being formed of N symbols;  
 a frequency-offset compensation means for compensating a frequency offset contained in said received packet based on said frequency offset estimation; and  
 a channel impulse response estimation means for estimating an impulse response of a channel based on an output for which the frequency offset is compensated .  
 
     
     
       3. The packet receiver defined in claim  2    14 , wherein:
 an auto-correlation function of said N symbol sequences is in an impulse state; and  
 said channel impulse response estimation means comprises means for estimating a channel impulse response based on a sequence for which the auto-correlation function is in an impulse state, and a received training sequence.  
 
     
     
       4. The packet receiver defined in  claim 2 , wherein said frequency offset estimation means comprises:
 a delay circuit for delaying said received packet by a transmission period of time of a sequence of N-symbol sequences;  
 a phase difference detection circuit for detecting a phase difference between an output of said delay circuit and said received packet;  
 an integrator for integrating a detection output of said phase difference detection circuit over a transmission period of time of a sequence of M symbols (where M is an integer of 2  1 or more); and  
 a divider circuit for dividing an output of said integrator by a product of N and M.  
 
     
     
       5. The packet receiver defined in claim  2    14 , wherein said impulse response estimation means outputs a channel impulse response estimation value after inputting a pulse representing that said frequency offset estimation means has completed frequency offset estimation. 
     
     
       6. A packet receiver for receiving packets, each of said packets including a training portion and a data portion used to initially set a receiver, said training portion being formed by serially connecting K sequences (where K is an integer of 2 or more), each of K sequences being formed of N symbols (where N is an integer of 2  1 or more), said packet receiver comprising  comprises:
 a frequency offset estimation means for detecting a phase difference between a sequence received prior to NT (where T is a continuous time of one symbol) and a currently received sequence, and for estimating a frequency offset based on said phase difference;  
 a frequency offset compensation means for compensating said frequency offset by rotating the phase of a received signal in the frequency offset compensation direction based on a frequency offset estimation value; and  
 a channel impulse estimation means for estimating an impulse response of a channel based on an output from an output for which the frequency offset is compensated .  
 
     
     
       7. The packet receiver defined in claim  6    15 , wherein an auto-correlation function of said N symbol sequences is in an impulse state; and wherein said channel impulse response estimation means comprises means for estimating a channel impulse response based on a sequence in which the auto-correlation function is in an impulse state, and a received training sequence. 
     
     
       8. The packet receiver defined in claim  6    15 , wherein said impulse response estimation means outputs a channel impulse response estimation value after inputting a pulse representing that said frequency offset estimation means has completed frequency offset estimation. 
     
     
       9. A packet receiving method for receiving packets, each of said packets including a training portion and a data portion to initially set a receiver, said training portion being formed by serially connecting K sequences (where K is an integer of 2 or more), each of said K sequences being formed of N symbols (where N is an integer of 2  1 or more), said method comprising  comprises:
 estimating a frequency offset based on a phase difference between two neighboring sequences of K sequences of a received packet, each of K sequences being formed of N symbols;  
 compensating a frequency offset contained in said received packet based on a frequency offset estimation value; and  
 estimating an impulse response of a channel based on a received packet of which the frequency offset is compensated .  
 
     
     
       10. The packet receiving method defined in claim  9    16 , wherein said step of estimating an impulse response of said channel comprises estimating a channel impulse response by placing an auto-correlation function of said sequence of N symbols in an impulse state, and detecting a peak value of an autocorrelation value between a received signal and said sequence of N symbols. 
     
     
       11. The packet receiving method defined in claim  9    16 , wherein said step of estimating an impulse response of said channel comprises the step of outputting a channel impulse response estimation value after frequency offset estimation has been completed. 
     
     
       12. A method of configuring packets, said packets each including a training portion and a data portion, the method comprising forming said training portion by serially connecting K sequences ( where K is an integer of  2  or more ) , each of said K sequences being formed of N symbol ( s ) ( where N is an integer of  1  or more ) , wherein a phase difference between two neighboring sequences of said K sequences is used for frequency - offset estimation.   
     
     
       13. The packet receiver as claimed in  claim 2 , further comprising:
   a frequency - offset compensation means for compensating a frequency offset contained in said received packet based on said frequency offset estimation; and        a channel impulse response estimation means for estimating an impulse response of a channel based on an output for which the frequency offset is compensated.     
     
     
       14. The packet receiver as claimed in  claim 6 , further comprising:
   a frequency offset compensation means for compensating said frequency offset by rotating the phase of a received signal in the frequency offset compensation direction based on a frequency offset estimation value; and        a channel impulse estimation means for estimating an impulse response of a channel based on an output from an output for which the frequency offset is compensated.     
     
     
       15. The packet receiving method as claimed in  claim 9 , further comprising:
   compensating a frequency offset contained in said received packet based on a frequency offset estimation value; and        estimating an impulse response of a channel based on a received packet of which the frequency offset is compensated.     
     
     
       16. A packet transmitter that transmits packets, each packet including a training portion and a data portion, said training portion being formed by serially connecting K sequences ( where K is an integer of  2  or more ) , wherein a phase difference between two neighboring sequences of said K sequences is used for frequency - offset estimation, each of said K sequences being formed of N symbols  ( where N is an integer of  1  or more ).

Cited by (0)

No later patents cite this yet.

References (0)

No backward citations on record.