Abstract: A dual mode, dual core power amplifier (PA) device includes a plurality of PA chains that generate output power according to an envelope tracking mode and a non-envelope tracking mode. The different modes can be selected to generate output power based on a set of predetermined criteria, which can be related to an input signal received by the system and related to a target power. A first PA chain with one or more PA cores is configured to operate in the envelope tracking mode based on at least a portion of the predetermined criteria being identified in the input signal and to generate output power with an envelope voltage supply that changes with an envelope of the input signal. In addition, a second PA chain with one or more PA cores can operate in a constant voltage supply mode or the non-envelope tracking mode according to the predetermined criteria.

Abstract: Envelope tracking (ET) is enabled in connection with single-band or multi-band transmission. One example system includes two or more power amplification components associated with distinct frequency bands, with at least one including a first power amplifier (PA) configured to operate in an ET mode, and at least one including a second PA configured to operate in an average power tracking (APT) mode of operation. A first DC-to-DC converter is configured to provide a first supply voltage according to the ET mode to each first PA, and a second DC-to-DC converter is configured to provide a second supply voltage according to the APT mode to each second PA. A control component is configured to determine a present transmission mode and to select on that basis one or more PAs, wherein the control component selects at most one of the first PAs and at most one of the second PAs.

Abstract: Compensation for one or more effects of impedance mismatch between a power amplifier (PA) and at least one filter is discussed. One example system that compensates for impedance mismatch with at least one filter comprises a PA, a measurement component, and a feedback component. The PA is configured to receive PA stimuli comprising a supply voltage and a radio frequency (RF) signal to be amplified, wherein a PA output is configured to be coupled to the at least one filter. The measurement component is coupled to the PA and configured to measure an output signal from the PA, wherein the output signal comprises a forward signal associated with the PA and a reflected signal associated with the at least one filter. The feedback component is configured to receive the output signal and to adjust one or more of the PA stimuli based at least in part on the output signal.

Abstract: An apparatus for controlling the generation of a radio frequency transmit signal includes a control module configured to control at least one power amplifier stimulus of a power amplifier module based on information related to at least one intermodulation product caused during generation of an amplified radio frequency transmit signal amplified by the power amplifier module. The amplified radio frequency transmit signal has at least two spectral clusters allocated for data transmission.

Abstract: An apparatus for amplifying a transmit signal includes a power amplifier module arranged within a transmit path to be coupled to an antenna module. The power amplifier module is configured to amplify a transmit signal. Further, the apparatus includes a coupling module arranged between the power amplifier module and the antenna module. The coupling module is configured to provide a reverse feedback signal substantially generated by a part of the amplified transmit signal reflected by the antenna module. Further, the apparatus includes a determining module configured to determine a delay information on a delay between the transmit path and an envelope tracking path based on at least the reverse feedback signal. Additionally, the apparatus includes a power supply module arranged within the envelope tracking path configured to vary a power supply of the power amplifier module based on a transmit signal envelope information with a temporal alignment depending on the delay information.

Abstract: A circuit for generating a radio frequency signal includes an amplifier configured to provide a radio frequency signal, the radio frequency signal being based on a baseband signal and a power supply configured to provide a variable supply voltage to the amplifier. A predistortion circuit is configured to modify the baseband signal; and a control circuit configured to control an operation mode of the predistortion circuit depending on a bandwidth of a radius of the baseband signal.

Abstract: A tunable matching network is configured to couple at least one filter with a power amplifier that is configured to operate in an envelope tracking (ET) mode of operation over a transmit band. A control component is configured to detect a present set of operating conditions of the power amplifier when the power amplifier operates in the ET mode of operation. The present set of operating conditions comprises a present frequency of operation, and the control component is further configured to transmit a control signal to the tunable matching network in response to the detected present set of operating conditions. The tunable matching network is further configured to adjust an impedance of the tunable matching network in response to the transmitted control signal such that one or more ET characteristics are optimized based at least in part on the present set of operating conditions.

Abstract: An amplifier module comprises an amplifier having an output, a coupler coupled to the output to receive a first signal provided at the output and a power detector to provide a power signal from the first signal. It further comprises an input to receive a second signal. A switch is provided that is disposed to provide the power signal or the second signal to a signal output in dependence of a control signal.

Abstract: A method for calibrating a transmitter includes operating the transmitter using a first transmitter setting; obtaining, via an external reference measuring device, a transmit power reference value indicative of a first transmit power of the transmitter corresponding to the first transmitter setting, and obtaining, using an internal measuring device of the transmitter or of a receiver associated with the transmitter, a first uncalibrated transmit power measurement value corresponding to the first transmit power. The method further includes calibrating the internal measuring device using the transmit power reference value and the first uncalibrated transmit power measurement value to provide a calibrated internal measuring device, operating the transmitter using a second transmitter setting, and obtaining, using the calibrated internal measuring device, a second transmit power measurement value indicative of a second transmit power corresponding to the second transmitter setting.

Abstract: A circuit for generating a radio frequency signal includes an amplifier configured to provide a radio frequency signal, the radio frequency signal being based on a baseband signal and a power supply configured to provide a variable supply voltage to the amplifier. A predistortion circuit is configured to modify the baseband signal; and a control circuit configured to control an operation mode of the predistortion circuit depending on a bandwidth of a radius of the baseband signal.

Abstract: Envelope tracking (ET) is enabled in connection with single-band or multi-band transmission. One example system includes two or more power amplification components associated with distinct frequency bands, with at least one including a first power amplifier (PA) configured to operate in an ET mode, and at least one including a second PA configured to operate in an average power tracking (APT) mode of operation. A first DC-to-DC converter is configured to provide a first supply voltage according to the ET mode to each first PA, and a second DC-to-DC converter is configured to provide a second supply voltage according to the APT mode to each second PA. A control component is configured to determine a present transmission mode and to select on that basis one or more PAs, wherein the control component selects at most one of the first PAs and at most one of the second PAs.

Abstract: A tunable matching network is configured to couple at least one filter with a power amplifier that is configured to operate in an envelope tracking (ET) mode of operation over a transmit band. A control component is configured to detect a present set of operating conditions of the power amplifier when the power amplifier operates in the ET mode of operation. The present set of operating conditions comprises a present frequency of operation, and the control component is further configured to transmit a control signal to the tunable matching network in response to the detected present set of operating conditions. The tunable matching network is further configured to adjust an impedance of the tunable matching network in response to the transmitted control signal such that one or more ET characteristics are optimized based at least in part on the present set of operating conditions.

Abstract: A dual mode, dual core power amplifier (PA) device includes a plurality of PA chains that generate output power according to an envelope tracking mode and a non-envelope tracking mode. The different modes can be selected to generate output power based on a set of predetermined criteria, which can be related to an input signal received by the system and related to a target power. A first PA chain with one or more PA cores is configured to operate in the envelope tracking mode based on at least a portion of the predetermined criteria being identified in the input signal and to generate output power with an envelope voltage supply that changes with an envelope of the input signal. In addition, a second PA chain with one or more PA cores can operate in a constant voltage supply mode or the non-envelope tracking mode according to the predetermined criteria.

Abstract: An antenna tuner control system includes an RF path, a lookup table and a state table analysis component. The RF path is configured to generate an RF signal. The lookup table has a state table that correlates antenna states with impedance values. The state table analysis component is configured to generate a tuner control signal from the RF signal using the lookup table.

Abstract: A description is given of a circuit having a transmitter having a first transmission stage for generating a first transmission signal according to a first standard and a bias stage for generating a bias signal for a second standard and a second transmission stage for generating a second transmission signal according to the second standard. The second transmission stage is effectively coupled to the bias stage in order to receive the bias signal.

Abstract: Arrangements are described for evaluating characteristics of target molecules. A biochip is received which includes a substrate to which charged probe molecules are attached. The probe molecules have a marker to allow generating signals indicative of the distance of a portion of the probe molecule from the substrate. The signals are detected and means for an external electric field is generated to which the probe molecules are exposed. A control means acts to: (A) apply an external electric field causing the portion of the probe molecule to approach the substrate, and (B) apply an external electric field causing the portion of the probe molecule to move away from the substrate. The signal is recorded as a function of time during step (A) and/or step (B). Steps (A) and (B) are repeated for a predetermined number of times and the recorded signals are combined.

Abstract: In an embodiment, a radio transmitter may be provided. The radio transmitter may include a radio transmitter control loop; and a controller configured in such a way that it operates the radio transmitter control loop as a closed control loop in a first operating mode, and that it operates the radio transmitter control loop as an open control loop in a second operating mode.

Abstract: An apparatus for amplifying a transmit signal comprises a transmit path comprising a power amplifier module to be coupled to an antenna module. The power amplifier module is configured to amplify a transmit signal. Further, the apparatus comprises an envelope tracking path comprising a variable delay module and a power supply module. The variable delay module is configured to vary a signal delay within the envelope tracking path according to a delay control parameter. Further, the apparatus comprises a delay control module configured to provide the delay control parameter based on a current characteristic transmit frequency of the transmit signal.

Abstract: The present invention is directed to sequencing of nucleic acids. A method is provided for sequencing based on immobilized nucleic acid on a surface. Advantageously, a long range detection mechanism is used for detecting, whether a nucleotide provided to the substrate of a biochip has been incorporated into the immobilized template nucleic acid. Various different alignment means are provided by the present invention which can be used for facilitating a rigidly locking of the orientation of the DNA complex, which complex comprises the template nucleic acid, the primer and the capture nucleic acid. Various different linker systems may be used to immobilize the DNA complex at a first and a second strand end, such that the desired alignment of the DNA complex is achieved. Also co-adsorbed molecules on the substrate surface can be used for such an aligning measure.

Abstract: Representative implementations of devices and techniques provide transmit power detection for an antenna of a wireless system having two or more transmit antennas. A correlation is reduced between a transmit signal of the antenna and signals from other antennas.