Device for ratiometric measurement of voltages for an analog-digital converter, wherein the device comprises a functional providing unit, a microcontroller and a first sensor, wherein a reference voltage is provided to the microcontroller and a first supply voltage is provided to the first sensor and the microcontroller by the functional providing unit, and wherein the first sensor is connected to the microcontroller in terms of signalling by transmitting sensor signals, and wherein the microcontroller comprises a first multiplexer and a second multiplexer, wherein the multiplexers outputs signals to the analog-digital-converter. According to the invention, it is provided that the reference voltage and the first supply voltage are in each case present on the input side at the first multiplexer and at the second multiplexer, wherein in a first switching state the first supply voltage can be measured on the output side by using the reference voltage as a reference for the analog-digital-converter and in a second switching state the reference voltage can be measured by using the first supply voltage as a reference for the analog-digital-converter.

In a control apparatus including a drive unit, first and second power supplies, a first diode, first and second control units, and a control method of the control apparatus, the first diode is connected to first and second power lines such that a direction from the second power line to the first power line is set as a forward direction, the second control unit is configured to calculate correction information for a first state value based on the voltage of the first power line before and after an abnormality has occurred in the first power supply and to transmit the correction information to the first control unit when the abnormality has occurred in the first power supply, and the first control unit is configured to correct the first state value using the correction information when the correction information has been received from the second control unit.

In a control apparatus including a drive unit, first and second power supplies, a first diode, first and second control units, and a control method of the control apparatus, the first diode is connected to first and second power lines such that a direction from the second power line to the first power line is set as a forward direction, the second control unit is configured to calculate correction information for a first state value based on the voltage of the first power line before and after an abnormality has occurred in the first power supply and to transmit the correction information to the first control unit when the abnormality has occurred in the first power supply, and the first control unit is configured to correct the first state value using the correction information when the correction information has been received from the second control unit.

A method and apparatus is provided the battery sensor for a large-scale battery system. More specifically, the present disclosure relates to the architecture and measurement scheme for a high-accuracy battery voltage sensor based on a calibration scheme. The present disclosure also related to the architecture and measurement method for a cell-level current sensor to effectively and reliably manage a battery pack.

A defect type classifying system includes: a measurer connected to a battery from which a defect type is detected, and measuring at least one of electrical characteristics of the battery for a predetermined test period and generating measured data; a converter for generating input data by converting the measured data; and a defect type predicting module for machine-learning learning data, and determining a defect type of the battery based on the input data. The input data may be appropriate for an input node of the defect type predicting module, and the defect type may be classified according to a cause of a short-circuit defect of the battery.

A defect type classifying system includes: a measurer connected to a battery from which a defect type is detected, and measuring at least one of electrical characteristics of the battery for a predetermined test period and generating measured data; a converter for generating input data by converting the measured data; and a defect type predicting module for machine-learning learning data, and determining a defect type of the battery based on the input data. The input data may be appropriate for an input node of the defect type predicting module, and the defect type may be classified according to a cause of a short-circuit defect of the battery.

According to certain aspects, a predictive tracking scheme is provided for sampling inductor currents in a digital PWM controller used for high-bandwidth voltage regulation. In one or more embodiments, the predicted current derived from the PWM waveform is fed forward to the current sense ADC in order to reduce the required conversion range. These and other embodiments only need to convert a few of the LSB of the ADC in order to correct the largest error expected in the synthesizer.

According to certain aspects, a predictive tracking scheme is provided for sampling inductor currents in a digital PWM controller used for high-bandwidth voltage regulation. In one or more embodiments, the predicted current derived from the PWM waveform is fed forward to the current sense ADC in order to reduce the required conversion range. These and other embodiments only need to convert a few of the LSB of the ADC in order to correct the largest error expected in the synthesizer.

In one or more embodiments, an efficient scheme is provided for sampling inductor currents in a digital multiphase PWM controller used for high-bandwidth voltage regulation. Some embodiments use the data from the PWM modulator along with weighted states based on the PWM waveform and past conversions in order to prioritize which current sense input should be sampled for each conversion. In these and other embodiments, a single ADC is used to sample inductor currents from two or more phases in a multiphase PWM controller, thereby providing power and area savings, for example.

In one or more embodiments, an efficient scheme is provided for sampling inductor currents in a digital multiphase PWM controller used for high-bandwidth voltage regulation. Some embodiments use the data from the PWM modulator along with weighted states based on the PWM waveform and past conversions in order to prioritize which current sense input should be sampled for each conversion. In these and other embodiments, a single ADC is used to sample inductor currents from two or more phases in a multiphase PWM controller, thereby providing power and area savings, for example.