The present invention relates to wireless communication technology, and more particularly, to a multi-mode wireless communication transmission method and apparatus.
Recently, various wireless communication technologies have been developed in conjunction with development of information and communication technology. Among the wireless communication technologies, a wireless local area network (WLAN) may allow users to wirelessly access the Internet at home, a workplace, or a service area using a portable terminal, for example, a personal digital assistant (PDA), a laptop computer, and a portable multimedia player (PMP), based on radio frequency (RF) technology. Since February in 1980 when the Institute of Electrical and Electronics Engineers (IEEE) 802, which is an organization for standardization of WLAN technology, was established, numerous standardization tasks have been conducted.
A wireless communication system has also been developed to transmit a large quantity of data at a high speed. Types of the wireless communication system may include, for example, a wireless broadband (WiBro) communication system, a third generation partnership project (3GPP) long term evolution (LTE) system, and a very high throughput (VHT) system of the WLAN. Accordingly, there is a desire for a transmission method for providing high efficiency and high performance while maintaining compatibility with an existing IEEE 802.11a/n/ac to transmit a next-generation WLAN frame, which is an next-generation WLAN standard.
According to an aspect of the present invention, there is provided a next-generation wireless local area network (WLAN) frame communication method, the communication method including modulating a first symbol in a signal field A (SIG-A) of a next-generation WLAN frame using a first modulation method, modulating a second symbol in the SIG-A of the next-generation WLAN frame using a second modulation method, and modulating a short training field (STF) signal of the next-generation WLAN in response to a next-generation WLAN mode.
In an example, the modulating of the first symbol may include modulating the first symbol in the SIG-A of the next-generation WLAN frame using binary phase-shift keying (BPSK). The modulating of the second symbol may include modulating the second symbol in the SIG-A of the next-generation WLAN frame using quadrature BPSK (Q-BPSK). The modulating of the STF signal may include modulating the STF signal of the next-generation WLAN frame to have a phase difference of 90 degrees (°) from a very high throughput (VHT)-STF signal.
In another example, the modulating of the first symbol may include modulating the first symbol in the SIG-A of the next-generation WLAN frame using BPSK. The modulating of the second symbol may include modulating the second symbol in the SIG-A of the next-generation WLAN frame using the BPSK. The modulating of the STF signal may include modulating the STF signal of the next-generation WLAN frame using Q-BPSK.
In still another example, a BPSK signal may be mapped to signal coordinates of (−1, 1) and (1, −1).
According to another aspect of the present invention, there is provided a next-generation WLAN frame communication method including receiving a communication signal, verifying a first symbol and a second symbol in an SIG-A of the communication signal, verifying an STF signal of the communication signal when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal, and identifying a communication mode of a next-generation WLAN frame based on the STF signal.
The identifying may include determining the communication mode to be a next-generation WLAN mode when the STF signal has a phase difference of 900 from a VHT-STF signal.
According to still another aspect of the present invention, there is provided a next-generation WLAN frame communication method including receiving a communication signal, verifying a first symbol and a second symbol in an SIG-A of the communication signal, verifying an STF signal of the communication signal when the first symbol is a BPSK signal and the second symbol is a BPSK signal, and identifying a communication mode of a next-generation WLAN frame based on the STF signal.
The identifying may include determining the communication mode to be a next-generation WLAN mode when the STF signal is a Q-BPSK signal.
According to yet another aspect of the present invention, there is provided a next-generation WLAN frame communication method including modulating a first symbol in an SIG-A of a next-generation WLAN frame using a first modulation method, modulating a second symbol in the SIG-A of the next-generation WLAN frame using a second modulation method, and modulating a third symbol in the SIG-A of the next-generation WLAN frame in response to a next-generation WLAN mode.
In an example, the modulating of the first symbol may include modulating the first symbol in the SIG-A of the next-generation WLAN frame using BPSK. The modulating of the second symbol may include modulating the second symbol in the SIG-A of the next-generation WLAN frame using Q-BPSK. The modulating of the third symbol may include modulating the third symbol in the SIG-A of the next-generation WLAN frame to have a phase difference of 90° from a VHT-STF signal.
In another example, the modulating of the first symbol may include modulating the first symbol in the SIG-A of the next-generation WLAN frame using BPSK. The modulating of the second symbol may include modulating the second symbol in the SIG-A of the next-generation WLAN frame using the BPSK. The modulating of the third symbol may include modulating the third symbol in the SIG-A of the next-generation WLAN frame using Q-BPSK.
According to a further aspect of the present invention, there is provided an next-generation WLAN frame communication method including receiving a communication signal, verifying a first symbol and a second symbol in an SIG-A of the communication signal, verifying a third symbol in the SIG-A when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal, and identifying a communication mode of a next-generation WLAN frame based on the third symbol.
The identifying may include determining the communication mode to be a next-generation WLAN mode when the third symbol has a phase difference of 90° from a VHT-STF signal.
According to still another aspect of the present invention, there is provided a next-generation WLAN frame communication method including receiving a communication signal, verifying a first symbol and a second symbol in an SIG-A of the communication signal, verifying a third symbol in the SIG-A when the first symbol is a BPSK signal and the second symbol is a BPSK signal, and identifying a communication mode of a next-generation WLAN frame based on the third symbol.
The identifying may include determining the communication mode to be a next-generation WLAN mode when the third symbol is a Q-BPSK signal.
According to still another aspect of the present invention, there is provided a next-generation WLAN frame communication method including generating a signal field (SIG) of a next-generation WLAN frame to have a length equal to an SIG of a VHT frame, and inputting, as a first value, a predetermined reserved bit among reserved bits in a structure of the SIG of the VHT frame.
The next-generation WLAN frame communication method may further include modulating a first symbol in an SIG-A of the next-generation WLAN frame using BPSK, and modulating a second symbol in the SIG-A of the next-generation WLAN frame using Q-BPSK.
The inputting may include inputting, as the first value, the predetermined reserved bit in a next-generation WLAN mode, and inputting, as a second value, the predetermined reserved bit in a VHT mode.
According to still another aspect of the present invention, there is provided a next-generation WLAN frame communication method including receiving a WLAN frame, verifying a predetermined reserved bit among reserved bits in a structure of an SIG of a VHT frame of the WLAN frame, and identifying a communication mode of the WLAN frame based on the identified reserved bit.
The identifying may include determining the communication mode to be a next-generation WLAN mode when the identified reserved bit is a first value, and determining the communication mode to be a VHT mode when the identified reserved bit is a second value.
According to still another aspect of the present invention, there is provided a next-generation WLAN frame communication method including generating an SIG of a next-generation WLAN frame to have a length equal to an SIG of a high throughput (HT) frame, and inputting, as a first value, a reserved bit in a structure of the SIG of the HT frame in a next-generation WLAN mode.
According to still another aspect of the present invention, there is provided a next-generation WLAN frame communication method including receiving a WLAN frame, verifying a reserved bit among reserved bits in a structure of an SIG of an HT frame of the WLAN frame, and identifying a communication mode of the WLAN frame based on the identified reserved bit.
These and/or other aspects, features, and advantages of the invention will become apparent and more readily appreciated from the following description of exemplary embodiments, taken in conjunction with the accompanying drawings of which:
Reference will now be made in detail to exemplary embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. Exemplary embodiments are described below to explain the present invention by referring to the accompanying drawings, however, the present invention is not limited thereto or restricted thereby.
When it is determined a detailed description related to a related known function or configuration that may make the purpose of the present invention unnecessarily ambiguous in describing the present invention, the detailed description will be omitted here. Also, terms used herein are defined to appropriately describe the exemplary embodiments of the present invention and thus may be changed depending on a user, the intent of an operator, or a custom. Accordingly, the terms must be defined based on the following overall description of this specification.
Referring to
The WLAN may support a transmission method of a legacy, an HT, and a VHT mode. The IEEE 802.11a/g may be classified as a legacy type, the IEEE 802.11n as the HT mode, and the IEEE 802.11ac as the VHT mode.
A WLAN system may transmit a PPDU by including, in a header field, signal information used for a receiving end to correctly restore the PPDU. The signal information may be vital to restore PPDU data and thus, may be transmitted using a lowest modulation and coding scheme (MCS) to be robust against channel variation and noise. As illustrated in
The L-STF may be used for carrier sensing to detect whether a signal is present in a currently used channel, automatic gain control to match a radio signal to be input to an antenna with an operation range of an analog circuit and an analog-to-digital converter (ADC), and coarse carrier frequency offset correction.
The L-LTF may be used for fine carrier frequency offset correction, symbol synchronization, and channel response estimation to demodulate the L-SIG, and the HT-SIG or the VHT-SIG. In addition, the L-LTF may be used to estimate a signal-to-noise ratio (SNR) by applying a principle of two symbols alternately repeating therewith.
Using iterative sequences such as the L-STF and the L-LTF may enable an estimation of various characteristics of a channel, for example, interference, Doppler shift, and delay spread.
Signal fields (SIGs) such as the L-SIG, the HT-SIG, and the VHT-SIG may include control information required to demodulate PPDU received by a terminal or an access point (AP). For example, the control information may include a packet length, MCS, a bandwidth and channel encoding method, beamforming, space-time block coding (STBC), a smoothing method, multiuser multiple-input and multiple-output (MU-MIMO), a short guard interval (SGI) mode. The VHT-SIG may be classified into the VHT-SIG-A for shared control information and the VHT-SIG-B for information dedicated to a multiuser (MU) group, and then transmitted. In addition, the control information may further include identification (ID) information such as a group ID and a partial association ID (PAID).
The L-SIG, the HT-SIG, and the VHT-SIG may be used to provide information on a type of a frame. The L-SIG, the HT-SIG, and the VHT-SIG may transmit a transmission symbol using binary phase shift keying (BPSK) or quadrature BPSK (Q-BPSK) to provide information as to which type of a frame a terminal receives. A Q-BPSK signal may be obtained by rotating a phase of a BPSK signal by 90°. Thus, the Q-BPSK may ensure a maximum orthogonality in comparison to the BPSK.
In a case of a 802.11n frame, the 802.11n frame may be recognized by transmitting two HT-SIG symbols using the Q-BPSK and detecting the two symbols whose phases are rotated by 90° from the BPSK of a legacy frame. Here, to transmit the 802.11n frame, a rate of the L-SIG may be set to 6 mega bit per second (Mbps), and a length may be described as a period of time during which the frame occupies a channel. Thus, when the rate is determined to be 6 Mbps, determination on which one of the BPSK and the Q-BPSK is used for detection of an HT frame may be performed.
In a case of a 802.11ac frame, a first symbol of the VHT-SIG is required to be transmitted using the BPSK and a second symbol of the VHT-SIG is required to be transmitted using the Q-BPSK. Since the first symbol is transmitted using the BPSK, an 11n device may recognize the frame as a legacy frame, and an 11ac device may recognize the frame as a VHT frame by recognizing the Q-BPSK with respect to the second symbol.
The HT-STF or the VHT-STF may be used to increase a gain control performance of an automatic gain control (AGC), and additional gain control may be required for using beamforming technology.
The HT-LTF or the VHT-LTF may be used for the terminal or the AP to estimate a channel. Dissimilar to the legacy standard, by the 802.11n or the 802.11ac standard, a throughput may be improved by increasing the number of carriers to be used, and a new LTF may be defined to restore data in addition to the L-LTF. The VHT-LTF may include a pilot signal for offset correction.
The DATA may include data information to be transmitted. The DATA may convert a media access control (MAC) layer PDU (MPDU) to a physical layer service data unit (PSDU), and include a service field and a tail bit to perform transmission.
Referring to
The DATA of the NGW frame may include a data tone and a pilot tone. Using a travelling pilot may enable a change in a transmission position of the pilot for each symbol and maintenance of a performance robust against a Doppler shift. Alternatively, a midamble in an NGW-LTF structure may be periodically included between data symbols. Using the midamble may enable a wireless terminal to more quickly adapt to a channel variation and a phase shift and thereby, improving a performance outdoors. In addition, since a guard interval length of the DATA is variable, the guard interval length may be variably adjusted by an indicator of the SIG based on a channel environment to achieve robustness against delay spread.
Referring to
The NGW-SIG-A may provide a single user with information on a packet length that may decode a packet, MCS, a bandwidth and channel encoding method, beamforming, STBC, smoothing, MU-MIMO, an SGI mode, a delay spread state, a channel quality, a group ID, a PAID, and the like.
The NGW-STF may enable fine gain control when applying a beamforming transmission method or a multiple antenna transmission method. The NGW-LTF may be used for channel estimation and phase correction, or phase tracking, to restore an NGW data frame.
The DATA may include a data value transmitted through a method suitable for the signal information. The DATA may include a periodic pilot sequence as a reference signal to track and correct a phase, a signal magnitude, a residual frequency offset, and the like in order to restore data transmitted based on information described in the SIG. The pilot sequence may operate in a traveling pilot mode or a fixed pilot mode depending on pilot sequence mode information described in the SIG. The fixed pilot mode may refer to a mode in which a position of a pilot is fixed and the pilot is present in an identical position for each symbol per datum, whereas the travelling pilot mode may refer to a mode in which a position of a pilot is periodically rotated for each symbol and the position of the pilot is restored to an original position after a predetermined number of symbols. Using the travelling pilot may enable overcoming of the channel variation by which a channel state is significantly changed due to the Doppler shift or the delay spread.
Referring to
An HT frame 320 transmitting method may be performed using a Q-BPSK modulation method for a first symbol and a second symbol in an SIG.
A VHT frame 330 transmitting method may be performed using a BPSK modulation method for a first symbol in an SIG and using the Q-BPSK modulation method for a second symbol in the SIG.
Referring to
Referring to
An NGW (Type 2) frame transmitting method may be performed by including more sets of signal field information than an NGW (Type 1) frame transmitting method by transmitting a symbol in an NGW-SIG-A to be three symbol lengths.
Referring to
Referring to
According to an embodiment, a next-generation WLAN frame communication method may include determining a type of a frame by modulating and transmitting a symbol. In the next-generation WLAN frame communication method, a description of a method of transmitting frame type information included in an SIG will be provided with reference to
As described with reference to
As provided in the foregoing description of the VHT frame 530 transmitting method, an NGW (Type-3) frame 540 transmitting method may maintain the modulation method to be identical to the VHT mode frame. However, the NGW (Type-3) frame 540 and the VHT frame 530 may be distinguished using a reserved bit. A method of distinguishing between the VHT mode and the NGW mode will be described in detail with reference to
The NGW (Type-3a) frame 610 transmitting method may be performed by modulating a first symbol in an NGW-SIG-A using BPSK and modulating a second symbol in the NGW-SIG-A using Q-BPSK. Thus, a legacy terminal and an HT terminal may be recognized as a legacy mode, and a VHT terminal may be recognized as the VHT mode. An NGW terminal may determine the NGW mode using the reserved bit.
The NGW (Type-3b) frame 650 transmitting method may be performed using BPSK for a first symbol in an NGW-SIG-A, and Q-BPSK for a second symbol in the NGW-SIG-A. Thus, a legacy terminal and an HT terminal may recognize a legacy mode, and a VHT terminal may recognize the VHT mode. An NGW terminal may determine the NGW mode using the reserved bit.
Referring to
A modulation method of the SIGs of the NGW (Type-3a) and the NGW (Type-3b) frames may be identically performed as in a VHT mode frame, and performed for an NGW device to recognize an NGW frame mode using reserved bits. An L-SIG may not be easily used to detect a frame mode because a performance of determining an occurrence of an error of a parity bit may decrease and a reserved bit may be already used for another purpose. However, an HT-SIG or a VHT-SIG may have a cyclic redundancy check (CRC) field and a highly desirable error detecting performance and thus, may be used to detect the frame mode.
Referring to
An NGW (Type-4) frame 840 transmitting method may be performed using the Q-BPSK modulation method for both the two symbols same as in the HT-SIG. Thus, an HT device and a VHT device may recognize the frame as an HT frame, and a legacy device may recognize the frame as a legacy frame. An NGW device may determine whether the frame is an NGW frame using a reserved bit. For example, when the reserved bit is “0,” the frame may be recognized as the NGW frame. When the reserved bit is “1,” the frame may be recognized as the HT frame.
Referring to
Referring to
Referring to
In operation 1020, the transmitter modulates a second symbol in the SIG-A of the NGW frame using Q-BPSK.
In operation 1030, the transmitter modulates an STF signal of the NGW frame to have a phase difference of 90° from a VHT-STF signal. The NGW-STF signal may be transmitted with a BPSK signal being mapped to (−1, 1) and (1, −1) coordinates, and the VHT-STF signal may be transmitted with a BPSK signal being mapped to (1, 1) and (−1, −1) coordinates. Thus, the NGW-STF signal and the VHT-STF signal may be modulated to have the phase difference of 900 therebetween.
The next-generation WLAN frame communication apparatus may recognize the frame as a VHT or an NGW frame based on the BPSK and the Q-BPSK signal in the SIG, and recognize a frame mode by recognizing a phase of the STF signal.
Referring to
In operation 1120, the receiver verifies a first symbol and a second symbol in an SIG-A of the communication signal.
In operation 1130, the receiver verifies an STF signal of the communication signal when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal.
In operation 1140, the receiver identifies a communication mode of a WLAN frame based on the STF signal. When an NGW-STF signal has a phase difference of 90° from a VHT-STF signal, the receiver may determine the communication mode to be a next-generation WLAN mode. When the NGW-STF signal has no phase difference from the VHT-STF signal, the receiver may determine the communication mode to be a VHT mode.
Referring to
In operation 1220, the transmitter modulates a second symbol in the SIG-A of the NGW frame using the BPSK.
In operation 1230, the transmitter modulates an STF signal of the NGW frame using Q-BPSK.
Referring to
In operation 1320, the receiver verifies a first symbol and a second symbol in an SIG-A of the communication signal.
In operation 1330, the receiver verifies an STF signal of the communication signal when the first symbol is a BPSK signal and the second symbol is a BPSK signal.
In operation 1340, the receiver identifies a communication mode of a WLAN frame based on the STF signal. When the STF signal is a Q-BPSK signal, the receiver may identify the communication mode to be a next-generation WLAN mode. When the STF signal is a BPSK signal, the receiver may identify the communication mode to be a legacy mode.
Referring to
In operation 1420, the transmitter modulates a second symbol in the SIG-A of the NGW frame using Q-BPSK.
In operation 1430, the transmitter modulates a third symbol in the SIG-A of the NGW frame to have a phase difference of 90° from a VHT-STF signal. In the STF signal, a BPSK signal may be mapped to (−1, 1) and (1, −1) signal coordinates.
Referring to
In operation 1520, the receiver verifies a first symbol and a second symbol in an SIG-A of the communication signal.
In operation 1530, the receiver verifies a third symbol in the SIG-A when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal.
In operation 1540, the receiver identifies a communication mode of a WLAN frame based on the third symbol. When the third symbol has a phase difference of 90° from a VHT-STF signal, the receiver may determine the communication mode to be a next-generation WLAN mode. When the third symbol has no phase difference from the VHT-STF signal, the receiver may determine the communication mode to be a VHT mode.
Referring to
In operation 1620, the transmitter modulates a second symbol in the SIG-A of the NGW frame using the BPSK.
In operation 1630, the transmitter modulates a third symbol in the SIG-A of the NGW frame using Q-BPSK.
Referring to
In operation 1720, the receiver verifies a first symbol and a second symbol in an SIG-A of the communication signal.
In operation 1730, the receiver verifies a third symbol in the SIG-A when the first symbol is a BPSK signal and the second symbol is a BPSK signal.
In operation 1740, the receiver identifies a communication mode of a WLAN frame based on the third symbol in the SIG-A. When the third symbol in the SIG-A is a Q-BPSK signal, the receiver may determine the communication mode to be a next-generation WLAN mode. When the third symbol in the SIG-A is a BPSK signal, the receiver may determine the communication mode to be a legacy mode.
Referring to
In operation 1820, the transmitter inputs, as a first value, a reserved bit among reserved bits in the structure of the SIG of the VHT frame. For example, the transmitter may input, as the first value, a predetermined reserved bit among the reserved bits in the structure of the SIG of the VHT frame. In a next-generation WLAN mode, the transmitter may input the predetermined reserved bit as the first value. In a VHT mode, the transmitter may input the predetermined reserved bit as a second value.
In operation 1830, the transmitter modulates a first symbol in an NGW-SIG-A of the NGW frame using BPSK. In operation 1840, the transmitter modulates a second symbol in the NGW-SIG-A of the NGW frame using Q-BPSK.
Referring to
In operation 1920, the receiver identifies a predetermined reserved bit among reserved bits in a structure of an SIG of a VHT frame of the WLAN frame.
In operation 1930, the receiver identifies a communication mode of the WLAN frame based on the identified reserved bit. When the reserved bit is a first value, the receiver may determine the communication mode to be a next-generation WLAN mode. When the reserved bit is a second value, the receiver may determine the communication mode to be a VHT mode. For example, when the reserved bit is “0,” the receiver may determine the communication mode to be the next-generation WLAN mode. When the reserved bit is “1,” the receiver may determine the communication mode to be the VHT mode.
Referring to
In operation 2020, the transmitter inputs, as the first value, a reserved bit in the structure of the SIG of the HT frame.
In operation 2030, the transmitter modulates a first symbol in an NGW-SIG-A of the NGW frame using Q-BPSK. In operation 2040, the transmitter modulates a second symbol in the NGW-SIG-A of the NGW frame using the Q-BPSK.
Referring to
In operation 2120, the receiver identifies a reserved bit in a structure of an SIG of an HT frame of the WLAN frame.
In operation 2130, the receiver identifies a communication mode of the WLAN frame based on the identified reserved bit. When the reserved bit is a first value, the communication mode may be determined to be a next-generation WLAN mode. When the reserved bit is a second value, the communication mode may be determined to be an HT mode.
According to an embodiment, a next-generation WLAN frame communication apparatus may be compatible with IEEE 802.11a/n/ac, and transmit a distinguishable high-efficiency and high-performance NGW frame.
Referring to
During the delivery of the PSDU received from the MAC sublayer to be transmitted to the PMD sublayer, the PLCP sublayer may append a field including required information by a physical layer transmitter and receiver. The field to be appended may include, in the PSDU, a PLCP preamble, a PLCP header, a tail bit to initialize a state of a convolutional encoder, and the like.
The PLCP preamble may include a periodic and iterative sequence to match synchronization and control a gain for a receiver to successfully restore the PSDU, or to verify a channel state. The PLCP header may include sets of information required for restoration of the PSDU. For example, the PLCP header may include a packet length, a bandwidth, technology used for MCS and transmission, and the like. A data field may include an encoded sequence obtained as a service field including an initialization sequence for initializing a scrambler and tail bits are appended to one another. The data field may be modulated and encoded based on a transmission type included in the PLCP header and then be transmitted. The PLCP sublayer at a transmitting end may generate a PPDU and transmit the generated PPDU through the PMD sublayer. The PLCP sublayer at a receiving end may receive the PPDU, perform synchronization and gain control based on the PLCP preamble, obtain channel state information, and perform restoration by obtaining information required for packet restoration through the PLCP header.
In the IEEE 802.11ac standard, a 20 megahertz (MHz) or a 40 MHz bandwidth mode, which is supported by the IEEE 802.11n standard, may be supported, and a 80 MHz bandwidth may also be supported. In accordance with the IEEE 802.11ac standard, transmission may be performed using two non-contiguous 80 MHz simultaneously, which is referred to as non-contiguous 160 MHz bandwidth signal transmission. In addition, contiguous 160 MHz bandwidth signal transmission may also be possible. An AP supporting the IEEE 802.11ac standard may transmit a packet to at least one terminal simultaneously using MU-MIMO transmission technology. In a basic service set of a WLAN, the AP may simultaneously transmit data, which is classified into different spatial streams, to groups including at least one terminal among a plurality of terminals associated with the AP. In addition, the AP may also transmit the data to one terminal using a signal-user MIMO (SU-MINO) method. When beamforming technology is supported between the AP and a terminal belonging to a network, transmission to a single terminal or a terminal group may be performed to increase a signal gain. A group ID may be allocated to a terminal group to support MU-MINO transmission. The AP may allocate and distribute the group ID by transmitting a group ID management frame. A terminal may receive a plurality of group IDs. A WLAN terminal or the AP may support different functions depending on a vendor who implements a system and produces a chip. In the standard, optional items to be implemented may be stipulated in addition to mandatory items. Functions to be supported may be different depending on an implemented version of a standard. For example, although convolutional encoding technology is one of the mandatory items, low density parity check (LDPC) technology may be an optional item to be implemented. In addition, beamforming, MU-MIMO, and 160 MHz bandwidth support may also be optional items.
Referring to
Number | Date | Country | Kind |
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10-2013-0128672 | Oct 2013 | KR | national |
10-2014-0004562 | Jan 2014 | KR | national |
This application is a continuation application of U.S. application Ser. No. 16/905,708 filed on Jun. 18, 2020, which is a continuation application of U.S. application Ser. No. 14/525,047, filed on Oct. 27, 2014, and claims the priority benefit of Korean Patent Application No. 10-2013-0128672, filed on Oct. 28, 2013, and Korean Patent Application No 10-2014-0004562, filed on Jan. 14, 2014, in the Korean Intellectual Property Office, the disclosures of which are incorporated herein by reference. The foreign priority documents have been retrieved in U.S. application Ser. No. 14/525,047.
Number | Date | Country | |
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Parent | 16905708 | Jun 2020 | US |
Child | 18393415 | US | |
Parent | 14525047 | Oct 2014 | US |
Child | 16905708 | US |