A method of decoding multiple transmissions of time related data is provided. The method comprises receiving and recognizing separate data blocks, each data bock having data that comprises at least a code word assigned to a system frame number that depends on the transmission time of the respective data block; demodulating each data block in order to obtain IQ-samples, likelihood ratios or representatives thereof for each data block; accumulating the IQ-samples, likelihood ratios or representatives thereof to a sum that is forwarded to a single-block decoder; and decoding the sum, thereby obtaining decoding results. Further, a device for decoding multiple transmissions of time related data as well as a method of verifying a device for decoding multiple transmissions of time related data are described.

A method for automatically detecting a packet mode in a wireless communication system supporting a multiple transmission mode includes: acquiring at least one of data rate information, packet length information and channel bandwidth information from a transmitted frame; and determining the packet mode on the basis of the phase rotation check result of a symbol transmitted after a signal field signal and at least one of the data rate information, the packet length information and the channel bandwidth information acquired from the transmitted frame.

A method of decoding multiple transmissions of time related data is provided. The method comprises receiving and recognizing separate data blocks, each data bock having data that comprises at least a code word assigned to a system frame number that depends on the transmission time of the respective data block; demodulating each data block in order to obtain IQ-samples, likelihood ratios or representatives thereof for each data block; accumulating the IQ-samples, likelihood ratios or representatives thereof to a sum that is forwarded to a single-block decoder; and decoding the sum, thereby obtaining decoding results. Further, a device for decoding multiple transmissions of time related data as well as a method of verifying a device for decoding multiple transmissions of time related data are described.

A synchronized in-phase/quadrature phase (I/Q) detection circuit and a method of the same are provided. The synchronized I/Q detection circuit includes a first logic circuit; a first filter; a first reset and sampling circuit; a first multiplexer; a second logic circuit; a second filter; a second reset and sampling circuit; a signal generator; and a comparator.

A system and a method that enable two or more dispersed platforms to simultaneously use respective frequency-modulated continuous-wave radar systems in a typical radar application such as synthetic-aperture radar for terrain mapping, moving-target indicator radar to track targets on the ground and air-to-air tracking of other aircraft. The systems use the same RF spectrum in their operation and also communicate through their respective radar systems while simultaneously reducing their interplatform interference through the use of both filters and coded waveforms.

A method and an apparatus for measuring a displacement of an object according to steps of: dividing a signal into an I signal and a Q signal according to a phase of the signal, wherein the signal is reflected by the object after a transmission signal having a plurality of frequencies is emitted toward the object by the radar measurement system; estimating a direct current (DC) component from an N-tuple information acquired from the I signal and the Q signal; removing the estimated DC component to correct the I signal and the Q signal; and measuring the displacement of the object based on the corrected I signal and Q signal are provided.

In general, a system is described that includes two computing devices, a first which is configured to operate using a first wireless protocol and a second which is configured to operate using a second wireless protocol different than the first wireless protocol. The first computing device may determine a symbol to be sent to the second computing device. For each bit included in a payload of a data packet, the first computing device may set a value of the respective bit such that the symbol, when the data packet is translated into at least one signal using the first wireless protocol, is readable using the second wireless protocol. The first computing device generates the signal using the first wireless protocol, and outputs, via the first wireless protocol, the at least one signal. The second computing device may receive the at least one signal and demodulate the payload.

A method for automatically detecting a packet mode in a wireless communication system supporting a multiple transmission mode includes: acquiring at least one of data rate information, packet length information and channel bandwidth information from a transmitted frame; and determining the packet mode on the basis of the phase rotation check result of a symbol transmitted after a signal field signal and at least one of the data rate information, the packet length information and the channel bandwidth information acquired from the transmitted frame.

A method of transmitting a Physical Layer Convergence Procedure (PLCP) frame in a Very High Throughput (VHT) Wireless Local Area Network (WLAN) system includes generating a MAC Protocol Data Unit (MPDU) to be transmitted to a destination station (STA), generating a PLCP Protocol Data Unit (PPDU) by adding a PLCP header, including an L-SIG field containing control information for a legacy STA and a VHT-SIG field containing control information for a VHT STA, to the MPDU, and transmitting the PPDU to the destination STA. A constellation applied to some of Orthogonal Frequency Division Multiplex (OFDM) symbols of the VHT-SIG field is obtained by rotating a constellation applied to an OFDM symbol of the L-SIG field.

Included are a first signal exchanger for exchanging a TXI signal and a TXQ signal output from a transmission baseband unit to signal paths and a TX control unit for controlling generation of the TXI signal and the TXQ signal in the transmission baseband unit on the basis of a measurement result of a reception baseband unit before and after exchange of the signals by the first signal exchanger. As a result, a transceiver only needs to have a single local signal generating unit mounted thereon as a local signal generating unit that is an analog circuit.