A battery monitoring system includes a battery monitoring ECU and battery monitoring devices which are sequentially connected in a connection configuration. The battery monitoring ECU includes a clock generator that generates a first clock signal. Each battery monitoring device includes a second clock generator that generates a second clock signal, a controller that causes a frequency correction block to correct a frequency of the second clock signal in line with the first clock signal and causes the battery monitor to monitor a battery cell using the second clock signal that has been corrected, and a switch that, according to an instruction of the battery monitoring ECU, switches a circuit configuration to a state in which a signal received from a preceding device is transmitted to a succeeding device in the connection configuration.

An apparatus includes a clock signal input, a sampling circuit, and an estimation circuit. The clock signal input receives N time measurements. A time measurement denotes a respective portion of a given cycle of a clock signal. The sampling circuit is to generate a first sampled window from the clock signal input. The first sampled window includes an accumulation of the N time measurements. The sampling circuit is to generate a second sampled window from the clock signal input including an accumulation of a plurality of products. The estimation circuit is to estimate the frequency or period of the clock signal based upon the first sampled window and the second sampled window.

An apparatus includes a clock signal input, a sampling circuit, and an estimation circuit. The clock signal input receives N time measurements. A time measurement denotes a respective portion of a given cycle of a clock signal. The sampling circuit is to generate a first sampled window from the clock signal input. The first sampled window includes an accumulation of the N time measurements. The sampling circuit is to generate a second sampled window from the clock signal input including an accumulation of a plurality of products. The estimation circuit is to estimate the frequency or period of the clock signal based upon the first sampled window and the second sampled window.

A method of driving a counter system with zero accumulated error includes setting a counter frequency of a counter transmitter, setting an original time count string according to the counter frequency, setting a first time count string of the counter greater than the original time count string, setting a second time count string of the counter smaller than the original time count string, and accumulating at least one first time count string and at least one second time count string over N cycles for generating a transmitter time count string. N is greater than two. A real time string generated by the original time count string over the N cycles is equal to the transmitter time count string.

A method of driving a counter system with zero accumulated error includes setting a counter frequency of a counter transmitter, setting an original time count string according to the counter frequency, setting a first time count string of the counter greater than the original time count string, setting a second time count string of the counter smaller than the original time count string, and accumulating at least one first time count string and at least one second time count string over N cycles for generating a transmitter time count string. N is greater than two. A real time string generated by the original time count string over the N cycles is equal to the transmitter time count string.

Systems, devices, and methods related to frequency converter arrangements are provided. For example, a frequency converter arrangement converts a first signal centered at a first frequency to a second signal centered at a second frequency different from the first frequency. The frequency converter arrangement includes local oscillator (LO) circuitry and in-phase, quadrature-phase (IQ) mixer circuitry coupled to the LO circuitry. The LO circuitry includes duty cycle correction circuitry to adjust a duty cycle of a pair of input clock signals. The duty cycle correction circuitry includes coarse tuning circuitry responsive to a digital calibration code, and analog tuning loop circuitry. The LO circuitry further includes quadrature divider circuitry coupled to an output of the duty cycle correction circuitry, where the quadrature divider circuitry generates an in-phase LO signal and a quadrature-phase LO signal from a pair of output clock signals at outputs of the duty cycle correction circuitry.

Systems, devices, and methods related to frequency converter arrangements are provided. For example, a frequency converter arrangement converts a first signal centered at a first frequency to a second signal centered at a second frequency different from the first frequency. The frequency converter arrangement includes local oscillator (LO) circuitry and in-phase, quadrature-phase (IQ) mixer circuitry coupled to the LO circuitry. The LO circuitry includes duty cycle correction circuitry to adjust a duty cycle of a pair of input clock signals. The duty cycle correction circuitry includes coarse tuning circuitry responsive to a digital calibration code, and analog tuning loop circuitry. The LO circuitry further includes quadrature divider circuitry coupled to an output of the duty cycle correction circuitry, where the quadrature divider circuitry generates an in-phase LO signal and a quadrature-phase LO signal from a pair of output clock signals at outputs of the duty cycle correction circuitry.

A method of driving a counter system with zero accumulated error includes setting a counter frequency of a counter transmitter, setting an original time count string according to the counter frequency, setting a first time count string of the counter greater than the original time count string, setting a second time count string of the counter smaller than the original time count string, and accumulating at least one first time count string and at least one second time count string over N cycles for generating a transmitter time count string. N is greater than two. A real time string generated by the original time count string over the N cycles is equal to the transmitter time count string.

A method of driving a counter system with zero accumulated error includes setting a counter frequency of a counter transmitter, setting an original time count string according to the counter frequency, setting a first time count string of the counter greater than the original time count string, setting a second time count string of the counter smaller than the original time count string, and accumulating at least one first time count string and at least one second time count string over N cycles for generating a transmitter time count string. N is greater than two. A real time string generated by the original time count string over the N cycles is equal to the transmitter time count string.

An apparatus includes a clock signal input, a sampling circuit, and an estimation circuit. The clock signal input receives N time measurements. A time measurement denotes a respective portion of a given cycle of a clock signal. The sampling circuit is to generate a first sampled window from the clock signal input. The first sampled window includes an accumulation of the N time measurements. The sampling circuit is to generate a second sampled window from the clock signal input including an accumulation of a plurality of products. The estimation circuit is to estimate the frequency or period of the clock signal based upon the first sampled window and the second sampled window.