Transmission device and method for transmitting data frame
First Claim
1. A transmission device, applied to a wireless local area network system using a multiple-input multiple-output (MIMO) technology, wherein the transmission device comprises:
- an acquiring unit, configured to;
acquire a long training field (LTF) parameters, andacquire a start position I of allocated subcarriers,wherein the LTF parameters comprise a frequency domain transform parameter and a time domain transform parameter that are required for generating an LTF sequence;
a frequency domain transform unit, configured to perform, according to the frequency domain transform parameter and the start position I acquired by the acquiring unit, a frequency domain transform on an LTF basic sequence to obtain an LTF symbol;
a time domain transform unit, configured to perform, according to the time domain transform parameter acquired by the acquiring unit, a time domain transform on the LTF symbol obtained by the frequency domain transform unit to obtain the LTF sequence; and
a sending unit, configured to;
add the LTF sequence obtained by the time domain transform unit to a first data frame, andsend the first data frame to a second device, so that the second device determines the LTF basic sequence according to the LTF sequence and performs channel estimation according to the LTF basic sequence,wherein the frequency domain transform parameter comprises a subcarrier quantity M for distinguishing spatial streams, a quantity L of elements in the LTF basic sequence, and a subcarrier quantity S; and
the frequency domain transform unit comprises;
a mapping module, configured to map, starting from the start position L at intervals of └
S/L┘
subcarriers, each element in the LTF basic sequence to a corresponding subcarrier to obtain a frequency domain LTF sequence, wherein └
┘
indicates round-down;
an inverse transform module, configured to perform an S-point inverse fast Fourier transform (IFFT) transform on the frequency domain LTF sequence obtained by the mapping module to obtain an LTF basic symbol; and
a generation module, configured to combine the LTF basic symbol obtained by the inverse transform module with a cyclic prefix (CP) to generate the LTF symbol.
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Abstract
A transmission device includes: an acquiring unit acquires LTF parameters, and acquires a start position I of allocated subcarriers, where the LTF parameters include a frequency domain transform parameter and a time domain transform parameter that are required for generating an LTF sequence; a frequency domain transform unit performs, according to the frequency domain transform parameter and the start position I, a frequency domain transform on an LTF basic sequence to obtain an LTF symbol; a time domain transform unit performs, according to the time domain transform parameter, a time domain transform on the LTF symbol to obtain the LTF sequence; and a sending unit adds the LTF sequence to a first data frame, and sends the first data frame to a second device, so that the second device determines the LTF basic sequence according to the LTF sequence and performs channel estimation according to the LTF basic sequence.
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Citations
11 Claims
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1. A transmission device, applied to a wireless local area network system using a multiple-input multiple-output (MIMO) technology, wherein the transmission device comprises:
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an acquiring unit, configured to; acquire a long training field (LTF) parameters, and acquire a start position I of allocated subcarriers, wherein the LTF parameters comprise a frequency domain transform parameter and a time domain transform parameter that are required for generating an LTF sequence; a frequency domain transform unit, configured to perform, according to the frequency domain transform parameter and the start position I acquired by the acquiring unit, a frequency domain transform on an LTF basic sequence to obtain an LTF symbol; a time domain transform unit, configured to perform, according to the time domain transform parameter acquired by the acquiring unit, a time domain transform on the LTF symbol obtained by the frequency domain transform unit to obtain the LTF sequence; and a sending unit, configured to; add the LTF sequence obtained by the time domain transform unit to a first data frame, and send the first data frame to a second device, so that the second device determines the LTF basic sequence according to the LTF sequence and performs channel estimation according to the LTF basic sequence, wherein the frequency domain transform parameter comprises a subcarrier quantity M for distinguishing spatial streams, a quantity L of elements in the LTF basic sequence, and a subcarrier quantity S; and the frequency domain transform unit comprises; a mapping module, configured to map, starting from the start position L at intervals of └
S/L┘
subcarriers, each element in the LTF basic sequence to a corresponding subcarrier to obtain a frequency domain LTF sequence, wherein └
┘
indicates round-down;an inverse transform module, configured to perform an S-point inverse fast Fourier transform (IFFT) transform on the frequency domain LTF sequence obtained by the mapping module to obtain an LTF basic symbol; and a generation module, configured to combine the LTF basic symbol obtained by the inverse transform module with a cyclic prefix (CP) to generate the LTF symbol. - View Dependent Claims (2, 3)
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4. A transmission device, applied to a wireless local area network system using a multiple-input multiple-output (MIMO) technology, wherein the transmission device comprises:
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an acquiring unit, configured to; acquire a long training field (LTF) parameters, and acquire a start position I of allocated subcarriers, wherein the LTF parameters comprise a frequency domain transform parameter and a time domain transform parameter that are required for generating an LTF sequence; a frequency domain transform unit, configured to perform, according to the frequency domain transform parameter and the start position I acquired by the acquiring unit, a frequency domain transform on an LTF basic sequence to obtain an LTF symbol; a time domain transform unit, configured to perform, according to the time domain transform parameter acquired by the acquiring unit, a time domain transform on the LTF symbol obtained by the frequency domain transform unit to obtain the LTF sequence; and a sending unit, configured to; add the LTF sequence obtained by the time domain transform unit to a first data frame, and send the first data frame to a second device, so that the second device determines the LTF basic sequence according to the LTF sequence and performs channel estimation according to the LTF basic sequence, wherein the frequency domain transform parameter comprises a subcarrier quantity M for distinguishing spatial streams, a quantity L of elements in the LTF basic sequence, and a subcarrier quantity S; and wherein the frequency domain transform unit comprises; a spread spectrum module, configured to perform, according to M, spread spectrum processing on each element in the LTF basic sequence to obtain an LTF spread spectrum sequence, wherein the LTF spread spectrum sequence comprises M*L elements; a mapping module, configured to map, starting from the start position I, each element in the LTF spread spectrum sequence obtained by the spread spectrum module to a corresponding subcarrier to obtain a frequency domain LTF sequence; an inverse transform module, configured to perform an S-point inverse fast Fourier transform (IFFT) transform on the frequency domain LTF sequence obtained by the mapping module to obtain an LTF basic symbol; and a generation module, configured to combine the LTF basic symbol obtained by the inverse transform module with a cyclic prefix (CP to generate the LTF symbol.
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5. A transmission device, applied to a wireless local area network system using a multiple-input multiple-output (MIMO) technology, wherein the transmission device comprises:
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a receiving unit, configured to receive a first data frame that carries a long training field (LTF) sequence and that is sent by a first device; a processing unit, configured to; determine an LTF basic sequence according to the LTF sequence received by the receiving unit, and perform channel estimation according to the LTF basic sequence; and an acquiring unit, configured to, before the processing unit determines the LTF basic sequence according to the LTF sequence; acquire LTF parameters, and acquire a start position I of allocated subcarriers, wherein the LTF parameters comprise a frequency domain transform parameter and a time domain transform parameter that are required for generating the LTF sequence by the first device, wherein the processing unit comprises; a time domain inverse transform subunit, configured to perform, according to the time domain transform parameter acquired by the acquiring unit, a time domain inverse transform on the LTF sequence to obtain an LTF symbol; and a frequency domain inverse transform subunit, configured to perform, according to the frequency domain transform parameter and the start position I acquired by the acquiring unit, a frequency domain inverse transform on the LTF symbol obtained by the time domain inverse transform subunit to obtain the LTF basic sequence, wherein the frequency domain transform parameter comprises a subcarrier quantity M for distinguishing spatial streams, a quantity L of elements in the LTF basic sequence, and a subcarrier quantity S, wherein the frequency domain inverse transform subunit comprises; a determining module, configured to determine an LTF basic symbol according to the LTF symbol, wherein the LTF symbol comprises the LTF basic symbol and a cyclic prefix (CP); a transform module, configured to perform an S-point fast Fourier transform (FFT) transform on the LTF basic symbol obtained by the determining module to obtain a frequency domain LTF sequence; and an extraction module, configured to extract, starting from the start position I, at intervals of └
S/L┘
subcarriers, the LTF basic sequence according to the frequency domain LTF sequence obtained by the transform module, wherein └
┘
indicates round-down. - View Dependent Claims (6)
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7. A method for transmitting a data frame, applied to a wireless local area network system using a multiple-input multiple-output (MIMO) technology, wherein the method comprises:
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acquiring, by a first device, a long training field (LTF) parameters, and acquiring a start position I of allocated subcarriers, wherein the LTF parameters comprise a frequency domain transform parameter and a time domain transform parameter that are required for generating an LTF sequence; performing, according to the frequency domain transform parameter and the start position I, a frequency domain transform on an LTF basic sequence to obtain an LTF symbol; performing, according to the time domain transform parameter, a time domain transform on the LTF symbol to obtain the LTF sequence; and adding the LTF sequence to a first data frame, and sending the first data frame to a second device, so that the second device determines the LTF basic sequence according to the LTF sequence and performs channel estimation according to the LTF basic sequence, wherein the frequency domain transform parameter comprises a subcarrier quantity M for distinguishing spatial streams, a quantity L of elements in the LTF basic sequence, and a subcarrier quantity S; wherein the performing, according to the frequency domain transform parameter and the start position I, a frequency domain transform on an LTF basic sequence to obtain an LTF symbol, comprises; mapping, starting from the start position I, at intervals of └
S/L┘
subcarriers, each element in the LTF basic sequence to a corresponding subcarrier to obtain a frequency domain LTF sequence, wherein └
┘
indicates round-down;performing an S-point inverse fast Fourier transform (IFFT) transform on the frequency domain LTF sequence to obtain an LTF basic symbol; and combining the LTF basic symbol with a cyclic prefix (CP) to generate the LTF symbol. - View Dependent Claims (8)
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9. A method for transmitting a data frame, applied to a wireless local area network system using a multiple-input multiple-output (MIMO) technology, wherein the method comprises:
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acquiring, by a first device, long training field LTF parameters, and acquiring a start position I of allocated subcarriers, wherein the LTF parameters comprise a frequency domain transform parameter and a time domain transform parameter that are required for generating an LTF sequence; performing, according to the frequency domain transform parameter and the start position L a frequency domain transform on an LTF basic sequence to obtain an LTF symbol; performing, according to the time domain transform parameter, a time domain transform on the LTF symbol to obtain the LTF sequence; and adding the LTF sequence to a first data frame, and sending the first data frame to a second device, so that the second device determines the LTF basic sequence according to the LTF sequence and performs channel estimation according to the LTF basic sequence, wherein the frequency domain transform parameter comprises a subcarrier quantity M for distinguishing spatial streams, a quantity L of elements in the LTF basic sequence, and a subcarrier quantity S; and the performing, according to the frequency domain transform parameter and the start position I, a frequency domain transform on an LTF basic sequence to obtain an LTF symbol, comprises; performing, according to M, spread spectrum processing on each element in the LTF basic sequence to obtain an LTF spread spectrum sequence, wherein the LTF spread spectrum sequence comprises M*L elements; mapping, starting from the start position I, each element in the LTF spread spectrum sequence to a corresponding subcarrier to obtain a frequency domain LTF sequence; performing an S-point IFFT transform on the frequency domain LTF sequence to obtain an LTF basic symbol; and combining the LTF basic symbol with a CP to generate the LTF symbol.
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10. A method for transmitting a data frame, applied to a wireless local area network system using a multiple-input multiple-output (MIMO) technology, the method comprising:
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receiving, by a second device, a first data frame that carries a long training field LTF sequence and that is sent by a first device; and determining an LTF basic sequence according to the LTF sequence, and performing channel estimation according to the LTF basic sequence; wherein, before the determining an LTF basic sequence according to the LTF sequence, the method further comprises; acquiring LTF parameters, and acquiring a start position I of allocated subcarriers, wherein the LTF parameters comprise a frequency domain transform parameter and a time domain transform parameter that are required for generating the LTF sequence by the first device, wherein the determining an LTF basic sequence according to the LTF sequence comprises; performing, according to the time domain transform parameter, a time domain inverse transform on the LTF sequence to obtain an LTF symbol; and performing, according to the frequency domain transform parameter and the start position L a frequency domain inverse transform on the LTF symbol to obtain the LTF basic sequence, wherein the frequency domain transform parameter comprises a subcarrier quantity M for distinguishing spatial streams, a quantity L of elements in the LTF basic sequence, and a subcarrier quantity S, and wherein the performing, according to the frequency domain transform parameter and the start position I, a frequency domain inverse transform on the LTF symbol to obtain the LTF basic sequence, comprises; determining an LTF basic symbol according to the LTF symbol, wherein the LTF symbol comprises the LTF basic symbol and a cyclic prefix (CP); performing an S-point fast Fourier transform (FFT) transform on the LTF basic symbol to obtain a frequency domain LTF sequence; and extracting, starting from the start position L at intervals of └
S/L┘
subcarriers, the LTF basic sequence according to the frequency domain LTF sequence, wherein └
┘
indicates round-down. - View Dependent Claims (11)
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Specification