A clock generation circuit includes: a frequency detector suitable for generating an internal clock, and generating a counting signal indicating a toggling number of the internal clock during an activation period of an input clock; a control signal generator suitable for generating a plurality of period control signals based on a target signal and the counting signal, the target signal indicating a target frequency of an output clock; and a period controller suitable for generating the output clock based on the period control signals.

A clock generation circuit includes: a frequency detector suitable for generating an internal clock, and generating a counting signal indicating a toggling number of the internal clock during an activation period of an input clock; a control signal generator suitable for generating a plurality of period control signals based on a target signal and the counting signal, the target signal indicating a target frequency of an output clock; and a period controller suitable for generating the output clock based on the period control signals.

The present invention provides an electronic device including a wireless communication module, a counter and a processing circuit. The wireless communication module is configured to receive a first packet and a second packet from another electronic device, wherein the first packet includes a first counter value, the second packet includes a second counter value, and the first counter value and the second counter value correspond to two adjacent edges of an original signal of another electronic device, respectively. The processing circuit is configured to obtain a third counter value from the counter when the first packet is received, and obtain a fourth counter value from the counter when the second packet is received; and the processing circuit further generates an output signal that is substantially the same as the original signal according to the first counter value, the second counter value, the third counter value and the fourth counter value.

Various embodiments relate to multi-modulus frequency dividers, devices including the same, and associated methods of operation. A method of operating a multi-modulus divider (MMD) may include receiving, at the MMD, an input signal at a first frequency. The method may also include generating, via the MMD, an output signal at a second, lower frequency based on a divisor value. Further, the method may include receiving, at the MMD, an integer value. Moreover, the method may include setting the divisor value equal to the integer value in response to a current state of the MMD matching a common state for the MMD, wherein the MMD is configured to enter the common state regardless of the divisor value.

A method of over-current protection includes: determining a current flowing through a first element to be protected, comparing the determined current with a plurality of thresholds, controlling a counter based on the comparing the determined current with a plurality of thresholds, and stopping the current flowing through the first element by activating a switch in series with the first element when an output of the counter reaches a predetermined counter threshold.

An improved circuit or method generates first and second initial pulses that do not overlap. First and second drive pulses are generated based on the first and second initial pulses, respectively. A first transistor is turned on with the first drive pulses. A second transistor is turned on with the second drive pulses. A current flows in response to an on-time state of the first transistor overlapping with an on-time state of the second transistor. A delay of the second drive pulses is decreased based on a time of the current flow overlapping with one of the first initial pulses; and the delay of the second drive pulses is increased based on the time of the current flow overlapping with one of the second initial pulses.

An improved circuit or method generates first and second initial pulses that do not overlap. First and second drive pulses are generated based on the first and second initial pulses, respectively. A first transistor is turned on with the first drive pulses. A second transistor is turned on with the second drive pulses. A current flows in response to an on-time state of the first transistor overlapping with an on-time state of the second transistor. A delay of the second drive pulses is decreased based on a time of the current flow overlapping with one of the first initial pulses; and the delay of the second drive pulses is increased based on the time of the current flow overlapping with one of the second initial pulses.

Fault detection circuitry and a corresponding method are disclosed. A count value that is indicative of the switching period of a PWM signal is determined and it is determined whether this count value is between a first threshold and a second threshold. An error signal is generated when the switching period is not between the first and the second threshold. A count value that is indicative of the switch-on duration of the PWM signal is determined and compared with a switch-on threshold in order to determine whether the switch-on duration is greater than a maximum switch-on duration. A count value that is indicative of the switch-off duration of the PWM signal is determined and compared with a switch-off threshold in order to determine whether the switch-off duration is greater than a maximum switch-off duration. Error signals can be generated when the durations are greater than the maximum durations.

According to an aspect of a present invention, there is provided a semiconductor device including a first power monitoring device and a second power monitoring device. The first power monitoring device outputs first operating power that is to be supplied to a second control section. The second power monitoring device outputs second operating power that is to be supplied to a first control section. Based on a first setting given from the first control section, a first power monitoring circuit autonomously verifies whether the second operating power is normal, and periodically transmits the result of verification to the second control section as first error information. Based on a second setting given from the second control section, a second power monitoring circuit autonomously verifies whether the first operating power is normal, and periodically transmits the result of verification to the first control section as second error information.

According to an aspect of a present invention, there is provided a semiconductor device including a first power monitoring device and a second power monitoring device. The first power monitoring device outputs first operating power that is to be supplied to a second control section. The second power monitoring device outputs second operating power that is to be supplied to a first control section. Based on a first setting given from the first control section, a first power monitoring circuit autonomously verifies whether the second operating power is normal, and periodically transmits the result of verification to the second control section as first error information. Based on a second setting given from the second control section, a second power monitoring circuit autonomously verifies whether the first operating power is normal, and periodically transmits the result of verification to the first control section as second error information.