Techniques related to signal processing include setting up a first operation mode or a second operation mode. In the first operation mode: providing a first analog signal to a first A/D converter by a first switch and a second analog signal to a second A/D by second switch, and converting the first analog signal to a first digital signal by the first A/D and the second analog signal to a second digital signal by the second A/D. In the second operation mode: demodulating a third analog signal to an in-phase signal and a quadrature signal by an I-Q-demodulator, providing the in-phase signal to the first A/D by the first switch, providing the quadrature signal to a second A/D by second switch, converting the in-phase signal to a third digital signal by the first A/D, and converting the quadrature signal to a fourth digital signal by the second A/D.

Techniques related to signal processing include setting up a first operation mode or a second operation mode. In the first operation mode: providing a first analogue signal to a first A/D converter by a first switch and a second analogue signal to a second A/D by second switch, and converting the first analogue signal to a first digital signal by the first A/D and the second analogue signal to a second digital signal by the second A/D. In the second operation mode: demodulating a third analogue signal to an in-phase signal and a quadrature signal by an I-Q-demodulator, providing the in-phase signal to the first A/D by the first switch, providing the quadrature signal to a second A/D by second switch, converting the in-phase signal to a third digital signal by the first A/D, and converting the quadrature signal to a fourth digital signal by the second A/D.

A MIMO transceiver has a plurality of analog processing subsystems that each includes at least one antenna, a duplexer, at least one power amplifier, at least one mixer, an interface connectable to a baseband processing subsystem, and the MIMO transceiver has one or more analog radio frequency processing chips. Each analog processing subsystem of the plurality of analog processing subsystems is on a single one of the analog radio frequency processing chips, and each analog radio frequency processing chip comprises a metallization on at least one side of the chip and wherein the metallization comprises integration of the at least one antenna.

A passive mixer may include an output coupled to a next stage circuit. The output may be coupled to baseband inputs via first switches. The passive mixer may further include a tunable capacitor bank. The tunable capacitor bank may be coupled via second switches to the baseband inputs.

A communication circuit may include mixers configured to generate voltage mode outputs. The communication circuit may further include voltage nodes configured to sum the voltage mode outputs produced by the mixers to generate intermediate voltage mode signals. The communication circuit may further include transconductors configured to convert the intermediate voltage mode signals to intermediate current mode signals. The communication circuit may further include at least one current node configured to sum the intermediate current mode signals to generate at least one mixer output signal.

A passive mixer may include an output coupled to a next stage circuit. The output may be coupled to baseband inputs via first switches. The passive mixer may further include a tunable capacitor bank. The tunable capacitor bank may be coupled via second switches to the baseband inputs.

An analog processing subsystem is disclosed. Said subsystem comprising at least one antenna (202,302), a duplexer (202a,302a), at least one power amplifier (203a,203b), at least one mixer (204a,204b, 304a, 304b) and an interface connectable to a baseband processing subsystem. The at least one mixer (204a,204b,304a,304b) is adapted to down-convert and inphase/quadratureIQdemodulate a received analog radio frequency signal, received by the at least one antenna (202,302), to provide a received analog baseband signal and to IQ-modulate and up-convert a transmit analog baseband signal, to be transmitted by the at least one antenna (202, 302), to provide a transmit analog radio frequency signal. The analog processing subsystem is comprised on a single analog radio frequency processing chip (201,301) comprising a metallization on at least one side of the chip for integration of the at least one antenna (202,302).

A method and terminal device for executing a radio application is disclosed. The method for executing a radio application is a method for executing a radio application independent of a modem in a terminal device, comprising the steps of: communicating with each other using a reconfigurable radio frequency interface (RRFI) by a unified radio application (URA), which operates on a radio computer of the terminal device, and a radio frequency (RF) transceiver, which operates in a radio platform on the radio computer; and supporting, by the RRFI, at least one service among a spectrum control service, a power control service, an antenna management service, a transmission/reception chain control service, and a radio virtual machine protection service.

The disclosure deals with methodology and system subject matter for a low-cost and portable millimeter-wave software-defined radio (SDR) which supports wireless experimentation in the 60 GHz band. The SDR uses a homodyne transceiver and provides a Transmission Control Protocol/Internet Protocol (TCP/IP)-based interface for companion computer (CC)-based baseband signal processing. To address the large difference between the processing speed of the CC and the sample rate of analog-to-digital converters, we use a disclosed method, called waveform-triggered reception (WTR), where a hard-coded block detects a special trigger waveform to acquire a predetermined number of in-phase/quadrature (IQ) data samples upon the detection. A buffer mechanism is used to support discontinuous transmissions. Using both the WTR and discontinuous transmissions, we can conduct a beam sweeping experiment, to evaluate 4096 beam pairs rapidly without compromising the flexibility of the CC-based processing.

At least one communication service for transmitting and/or receiving information associated with the communication service utilizes at least one of several antennas in a motor vehicle. An antenna circuit, associated with each of the antennas, converts an analog signal received by the antenna into digital received data associated with that antenna circuit and/or converts digital transmission data associated with that antenna circuit into an analog transmission signal which is supplied to the associated antenna. A communication device in the motor vehicle generates transmission data associated with the antenna circuits in accordance with transmission information and transfers the transmission data to the associated antenna circuit and receives the digital received data from at least one of the antenna circuits to provide reception information based on the digital received data.