The present disclosure relates to the technical field of lighting circuit, and more particularly to a lamp-apparatus circuit and a lamp apparatus. The lamp-apparatus circuit includes a drive module, a dimming module and a switch module for adjusting the current of the output terminal of the drive module, which are electrically connected. The dimming module includes a dimming circuit, a light-emitting circuit and a multi-position control circuit for controlling the dimming circuit to adjust the color temperature of the light-emitting circuit, which are electrically connected. The dimming module as a whole and the color temperature of the light-emitting circuit can be adjusted simply in operation. The color temperature adjustment means of the lamp apparatus are more diverse and more convenient, and the control circuit is a multi-position control circuit, which improves the flexibility of the color temperature adjustment of the lamp apparatus.

The present disclosure relates to the technical field of lighting circuit, and more particularly to a lamp-apparatus circuit and a lamp apparatus. The lamp-apparatus circuit includes a drive module, a dimming module and a switch module for adjusting the current of the output terminal of the drive module, which are electrically connected. The dimming module includes a dimming circuit, a light-emitting circuit and a multi-position control circuit for controlling the dimming circuit to adjust the color temperature of the light-emitting circuit, which are electrically connected. The dimming module as a whole and the color temperature of the light-emitting circuit can be adjusted simply in operation. The color temperature adjustment means of the lamp apparatus are more diverse and more convenient, and the control circuit is a multi-position control circuit, which improves the flexibility of the color temperature adjustment of the lamp apparatus.

A load control device for controlling the amount of power delivered to an electrical load is able to operate in a normal mode and a burst mode. The load control device may comprise a control circuit that activates an inverter circuit during active state periods and deactivates the inverter circuit during inactive state periods. The control circuit may operate in the normal mode to regulate an average magnitude of a load current conducted through the electrical load to be above a minimum rated current. The control circuit may operate in the burst mode to adjust the average magnitude of the load current to be below the minimum rated current. The control circuit may adjust the average magnitude of the load current by adjusting the length of the inactive state periods while holding the length of the active state periods constant.

A driving circuit for driving a light emitting unit is provided. The driving circuit includes a current source, a PWM circuit, and an emission switch. The current source generates a current. The PWM circuit stores a data signal according to a scan signal, and generates a PWM signal according to the data signal and an enable signal. The emission switch couples the current source to the light emitting unit according to the emission signal so that the current flows through the Light emitting unit.

A driving circuit for driving a light emitting unit is provided. The driving circuit includes a current source, a PWM circuit, and an emission switch. The current source generates a current. The PWM circuit stores a data signal according to a scan signal, and generates a PWM signal according to the data signal and an enable signal. The emission switch couples the current source to the light emitting unit according to the emission signal so that the current flows through the Light emitting unit.

A load control device for regulating an average magnitude of a load current conducted through an electrical load may operate in different modes. The load control device may comprise a control circuit configured to activate an inverter circuit during an active state period and deactivate the inverter circuit during an inactive state period. In one mode, the control circuit may adjust the average magnitude of the load current by adjusting the inactive state period while keeping the active state period constant. In another mode, the control circuit may adjust the average magnitude of the load current by adjusting the active state period while keeping the inactive state period constant. In yet another mode, the control circuit may keep a duty cycle of the inverter circuit constant and regulate the average magnitude of the load current by adjusting a target load current conducted through the electrical load.

A method for controlling an amount of power delivered to an electrical load may include controlling an average magnitude of a load current towards a target load current that ranges from a maximum rated current to a minimum rated current in a normal mode, and controlling the average magnitude of the load current below the minimum rated current in a burst mode. The burst mode may include at least one burst mode period that comprises a first time period associated with an active state and a second time period associated with an inactive state. During the burst mode, the method may include regulating a peak magnitude of the load current towards the minimum rated current during the active state, and stopping the generation of at least one drive signal during the inactive state to control the average magnitude of the load current to be less than the minimum rated current.

A driving circuit for driving a light emitting unit is provided. The driving circuit includes a current source, a PWM circuit, and an emission switch. The current source generates a current. The PWM circuit stores a data signal according to a scan signal, and generates a PWM signal according to the data signal and an enable signal. The emission switch couples the current source to the light emitting unit according to the emission signal so that the current flows through the Light emitting unit.

A driving circuit for driving a light emitting unit is provided. The driving circuit includes a current source, a PWM circuit, and an emission switch. The current source generates a current. The PWM circuit stores a data signal according to a scan signal, and generates a PWM signal according to the data signal and an enable signal. The emission switch couples the current source to the light emitting unit according to the emission signal so that the current flows through the Light emitting unit.

A control circuit includes a first light source, a second light source, an input channel for receiving an input signal, at most two output channels each configured to control one of the first light source and the second light source, where the control circuit is configured to use at most two cables, and is capable of permanently powering on one of the first light source and the second light source while, at the same time, flashing on and off the other of the first light source and the second light source.