An electronic circuit includes a peak detector, a gain controller, and a compressor. The peak detector detects a peak level from a digital input. The gain controller outputs a digital gain with regard to increasing the peak level to a target level, The compressor provides the gain controller with a compressed gain which is to be output as the digital gain, based on the detected peak level. In a compression interval where the peak level is greater than a threshold level, the output digital gain increases as the peak level decreases. The compressor generates the compressed gain such that a ratio of an increment of the output digital gain to a decrement of the peak level in the compression interval is less than a reference ratio.

A programmable gain amplifier includes an operational amplifier and a resistor network coupled to the output node of the operational amplifier. The resistor network includes a first plurality of resistors coupled in series between the output node and a first network node. A second plurality of resistors is coupled in series between the first network node and a second network node. A unit resistor is coupled in parallel with the second plurality of resistors between the first and second resistor network nodes and a third plurality of resistors is coupled in parallel between the second resistor network node and a reference voltage. Each resistor of the second and third pluralities of resistors comprises a unit resistor. The third plurality of resistors contains N resistors and the second plurality of resistors contains (N?1) resistors.

A radio-frequency signal preconditioning method includes: receiving, at a radio-frequency signal preconditioning apparatus from an antenna, a radio-frequency signal; selectively providing, at the radio-frequency signal preconditioning apparatus, any of a plurality of gains to the radio-frequency signal to produce an output signal, the plurality of gains spanning a first range; and providing, from the radio-frequency signal preconditioning apparatus, the output signal to a conversion circuit configured to convert the output signal from an analog signal at a radio frequency to a digital signal at a baseband frequency, the conversion circuit having a dynamic range spanning a second range that is smaller than the first range.

A method for operating a hearing device, in particular a hearing aid device, in which a first analog signal is provided. A second analog signal is generated by a preamplifier based on the first analog signal, and a first digital signal is generated by an A/D converter based on the second analog signal. A second digital signal is generated by an amplifier based on the first digital signal, and a third digital signal, in which a noise is reduced in comparison with the second digital signal, is generated by a noise suppression unit based on a second digital signal. The preamplifier, amplifier, and noise suppression unit are set using a value characterizing the first digital signal.

The present disclosure relates an automatic gain control apparatus and method for rapidly and effectively completing automatic gain control by performing a gain control procedure only three times irrespective of intensity of a received signal using peak values in an analog region and an output signal of an analog-digital converter.

Methods and systems are provided for gain control during communications. A first electronic device may communicated data to a second electronic device; may monitor conditions and/or parameters affecting estimated reception performance at the second electronic device; and may communicated to the second electronic device, via a connection separate from and different than a connection used in communicating the data, information relating to the monitored conditions, to enable adjusting functions relating to reception of the data at the second electronic device. Based on the received information, at least one reception related function in the second electronic device may be controlled. The controlling may include determining, based on the received information, adjustments to the at least one reception related function or to a related parameter. The at least one reception related function may include applying gain to at least a portion of signals received by the second electronic device.

A programmable gain amplifier includes an operational amplifier and a resistor network coupled to the output node of the operational amplifier. The resistor network includes a first plurality of resistors coupled in series between the output node and a first network node. A second plurality of resistors is coupled in series between the first network node and a second network node. A unit resistor is coupled in parallel with the second plurality of resistors between the first and second resistor network nodes and a third plurality of resistors is coupled in parallel between the second resistor network node and a reference voltage. Each resistor of the second and third pluralities of resistors comprises a unit resistor. The third plurality of resistors contains N resistors and the second plurality of resistors contains (N?1) resistors.

An electricity usage monitor may include a coupling component to attach the electricity usage monitor to an electrical circuit to monitor electricity usage of the electrical circuit, an analog-digital converter (ADC) configured to convert analog current readings captured by the electricity usage monitor into digital values, a processor operably coupled to the ADC, and a non-transitory, computer-readable medium operably coupled to the processor and comprising instructions which, when executed by the processor, cause the processor to perform operations. The operations may include determining a standard deviation of the digital values, based on the standard deviation, adjusting a gain of the ADC, and transmitting a signal to a server comprising the digital values.

An interleaved ADC receives an RX signal attenuated by a DSA based on an active DSA setting, within a range of DSA settings (DSA setting range) corresponding to selectable attenuation steps, the DSA setting range partitioned into a number of DSA setting subranges (DSA subranges). The ADC includes an IL mismatch estimation engine in the digital signal path, with an estimation subrange blanker, and an IL mismatch estimator. The estimation subrange blanker is coupled to receive the IADC data stream, and responsive to a DSA subrange allocation signal to select, in each of successive aggregation cycles, IADC data corresponding to an active DSA setting that is within an allocated DSA subrange (DSA active data within an DSA allocated subrange). The IL mismatch estimator aggregates, during each aggregation cycle, IL mismatch estimation data based on the selected DSA active data within the DSA allocated subrange, generates an estimate of IL mismatch (IL mismatch estimate) based on the aggregated IL mismatch estimation data, generates IL mismatch correction parameters based on the aggregated IL mismatch estimation data, and generates IL mismatch estimate uncertainty data corresponding to an uncertainty in the IL mismatch estimate used to generate the associated IL mismatch correction parameters for the DSA allocated subrange. A DSA statistics collector to collect a distribution of DSA settings over a pre-defined time period (DSA setting distribution statistics). An estimation subrange allocator coupled to receive DSA setting distribution statistics, and the IL mismatch estimate uncertainty data, and to provide to the estimation subrange blanker the DSA subrange allocation signal according to a pre-defined allocation strategy.

Various methods and systems are related to pulse-based automatic gain control. In one example, pulse-based automatic gain control (AGC) includes a variable gain amplifier (VGA) configured to amplify an analog input signal to generate an analog output signal based upon an amplification control signal; an integrate-and-fire (IF) sampler configured to generate a pulse train corresponding to the analog output signal; and a gain adjustment configured to generate the amplification control signal based upon a comparison of time between pulses of the pulse train to a reference time. In another example, a method includes determining time between pulses of a pulse train corresponding to an analog output signal from a VGA; generating an amplification control signal based upon a comparison of the time between pulses of the pulse train to a reference time; and adjusting amplification of the VGA in response to the amplification control signal.