An image forming apparatus comprises an ultrasonic sensor and a processor is configured to control the image forming apparatus based on an output signal of the ultrasonic sensor. The processor estimates a barometric pressure based on the output signal of the ultrasonic sensor and determines an image forming condition based on the estimated barometric pressure. The ultrasonic sensor is utilized for controlling the image forming apparatus and for estimating the barometric pressure.

An image forming apparatus comprises an ultrasonic sensor and a processor is configured to control the image forming apparatus based on an output signal of the ultrasonic sensor. The processor estimates a barometric pressure based on the output signal of the ultrasonic sensor and determines an image forming condition based on the estimated barometric pressure. The ultrasonic sensor is utilized for controlling the image forming apparatus and for estimating the barometric pressure.

An electronic fuse circuit includes an electronic switch with a load current path coupled between an output node and a supply node and that connects or disconnects the output node and the supply node in accordance with a drive signal. The circuit includes a control circuit to generate the drive signal based on an input signal. A monitoring circuit is included in the control circuit to receive a current sense signal representing the load current passing through the load current path and to determine a first protection signal based on the current sense signal and a wire parameter. The first protection signal is indicative of whether to disconnect the output node from supply node. The control circuit changes from normal mode to idle mode when the load current is below a given current threshold and another criterion is fulfilled.

An electronic fuse circuit includes an electronic switch with a load current path coupled between an output node and a supply node and that connects or disconnects the output node and the supply node in accordance with a drive signal. The circuit includes a control circuit to generate the drive signal based on an input signal. A monitoring circuit is included in the control circuit to receive a current sense signal representing the load current passing through the load current path and to determine a first protection signal based on the current sense signal and a wire parameter. The first protection signal is indicative of whether to disconnect the output node from supply node. The control circuit changes from normal mode to idle mode when the load current is below a given current threshold and another criterion is fulfilled.

A temperature delay device includes a first thermal sensor, a second thermal sensor, an inverter, and a latch circuit. The first thermal sensor is configured to measure a first temperature of a chip to output a first input signal. The second thermal sensor is configured to measure a second temperature of the chip to output a second input signal. The inverter is coupled to the first thermal sensor, and is configured to reverse the first input signal so as to output a third input signal. The latch circuit is coupled to the inverter and the second thermal sensor, and is configured to output an output signal according to the second input signal and the third input signal. The first temperature is different from the second temperature.

A temperature delay device includes a first thermal sensor, a second thermal sensor, an inverter, and a latch circuit. The first thermal sensor is configured to measure a first temperature of a chip to output a first input signal. The second thermal sensor is configured to measure a second temperature of the chip to output a second input signal. The inverter is coupled to the first thermal sensor, and is configured to reverse the first input signal so as to output a third input signal. The latch circuit is coupled to the inverter and the second thermal sensor, and is configured to output an output signal according to the second input signal and the third input signal. The first temperature is different from the second temperature.

An atmospheric turbulence detection method includes: providing a temperature difference measuring device including a thermocouple element and two sensing probes, wherein the thermocouple element has two opposite end portions, the two sensing probes are respectively disposed at the two end portions, and there is an ambient distance between the two end portions; placing the temperature difference measuring device in an atmospheric environment to generate an electromotive force by a temperature difference between the two end portions; analyzing the electromotive force to convert the electromotive force into an ambient temperature difference of an environment where the two end portions of the thermocouple element are located, an atmospheric refractive index structure constant is calculated according to the ambient temperature difference and the ambient distance, and a value of the atmospheric refractive index structure constant corresponds to an ambient disturbance of an atmospheric turbulence. An atmospheric turbulence detection device is also provided.

A power supply system includes: a voltage converter that converts a voltage between first and second power circuits; a power controller that controls charging and discharging of first and second batteries; a cooling output controller that controls cooling output for the second battery; a temperature remaining-capacity acquirer that acquires a temperature remaining-capacity T2_mar; and a cooling remaining-capacity acquirer that acquires a cooling remaining-capacity PC2_mar depending on a difference between maximum cooling output and the cooling output of the second cooler. The power controller is configured to stop the voltage converter in a case where at least one of the temperature remaining-capacity T2_mar and the cooling remaining-capacity PC2_mar is less than an associated one of a threshold value for the temperature remaining-capacity and a threshold value for the cooling remaining-capacity and a potential difference between the first and second batteries is equal to or more than a potential difference threshold value.

A power supply system includes: a voltage converter that converts a voltage between first and second power circuits; a power controller that controls charging and discharging of first and second batteries; a cooling output controller that controls cooling output for the second battery; a temperature remaining-capacity acquirer that acquires a temperature remaining-capacity T2_mar; and a cooling remaining-capacity acquirer that acquires a cooling remaining-capacity PC2_mar depending on a difference between maximum cooling output and the cooling output of the second cooler. The power controller is configured to stop the voltage converter in a case where at least one of the temperature remaining-capacity T2_mar and the cooling remaining-capacity PC2_mar is less than an associated one of a threshold value for the temperature remaining-capacity and a threshold value for the cooling remaining-capacity and a potential difference between the first and second batteries is equal to or more than a potential difference threshold value.

A temperature sensing circuit adapted for a memory device and including an oscillator, a count circuit, a control circuit, a sense circuit and a select circuit is provided. The oscillator provides an oscillation signal. The count circuit counts the oscillation signal to generate a first count signal, and generates a second count signal. The count circuit performs a logic operation on the second count signal to generate an enable signal and a sensing adjustment signal. The sense circuit generates a reference temperature voltage by dividing a reference voltage according to the sensing adjustment signal, and compares the reference temperature voltage and a monitor voltage according to the enable signal to generate a determination signal. The select circuit dynamically selects one of the oscillation signal and the first count signal according to the determination signal, and generates a pulse of a refresh request signal according to the dynamically selected one of the oscillation signal and the first count signal.