Lighting drive, lighting system and control method

The invention claimed is: 1. A lighting driver, comprising: a driver input adapted to receive an alternating current power supply from a fluorescent lighting ballast; a shunt device connected to the driver input and adapted to selectively shunt the power supply; a controller adapted to operate or not operate the shunt device; wherein the controller is adapted to operate the shunt device during a portion of a cycle of the alternating current power supply, such that a current is delivered to a lighting load only during the portion of the cycle of the alternating current power supply when the shunt device is not operated; and a zero crossing detector adapted to generate a detection signal and to provide the detection signal to the controller to operate the shunt device upon the detection signal, wherein said detection signal is a zero crossing detection signal, wherein the zero crossing detector comprises: a detection circuit adapted to analyze an input voltage at the driver input and generate the detection signal (ZCD) accordingly, when the input voltage is detected; and a correction circuit adapted to generate the detection signal (ZCD) after a time delay from an end of operating the shunt device, even when said input voltage is not detected, wherein said correction circuit is adapted to start to time a time constant corresponding to the time delay at the end of operating the shunt device and to generate the detection signal (ZCD) after the time constant expires when said input voltage is not detected. 2. The lighting driver as claimed in claim 1 , further comprising: a rectifier having a rectifier input adapted to connect to the driver input and having a rectifier output adapted to drive the lighting load, wherein the shunt device is either: connected between the rectifier and the lighting load, adapted to selectively shunt the rectifier output; or integrated with the rectifier and adapted to shunt the driver input, and wherein said detection circuit comprises: a pull on-off circuit adapted to: pull off the detection signal when the controller operates the shunt device; and pull off the detection signal when the input voltage at the driver input is low, and pull up the detection signal otherwise, when the controller does not operates the shunt device, and wherein the correction circuit is adapted to disable the pulling off of the pull on-off circuit after the controller stops from operating the shunt device, for the time delay. 3. The lighting driver as claimed in claim 1 , wherein the detection circuit is connected to the driver input and adapted to: detect non-zero voltage values and a zero voltage value of the input voltage; and determine a zero crossing of the input voltage at the driver input upon a detection of the zero voltage value as the zero crossing detection signal after the non-zero voltage value, and generating the detection signal (ZCD) when the non-zero voltage value is detected. 4. The lighting driver as claimed in claim 2 , wherein the detection circuit further comprises an interface circuit to the input voltage, and the pull on-off circuit comprises: a first pull off transistor associated with the interface circuit, wherein said first pull off transistor is adapted to enable the detection signal to be pulled on when the detected input voltage at the driver input is non-zero, and adapted to enable the detection signal to be pulled off when the detected input voltage at the driver input is zero. 5. The lighting driver as claimed in claim 4 , wherein the controller is adapted to generate a bi-state shunt control signal to control the shunt device, and the pull on-off circuit further comprises: a second pull off transistor, adapted to be controlled by the shunt control signal so as to pull off the detection signal (ZCD) when the shunt control signal operates the shunt device, and not to pull off the detection signal (ZCD) when the shunt control signal is not operating the shunt device. 6. The lighting driver as claimed in claim 5 , wherein the correction circuit is adapted to be controlled by the shunt control signal so as to enable the detection signal to be pulled on when the shunt control signal does not operate and hence when the second pull off transistor is not pulling off the detection signal, for the time delay. 7. The lighting driver as claimed in claim 6 , wherein the first pull off transistor comprises: a base terminal connected to a bias voltage and to the interface circuit; a collector terminal connected to a bias voltage; and an emitter terminal connected to a reference voltage (GND), and wherein the second pull off transistor comprises: a base terminal connected to the shunt control signal; a collector terminal connected to the collector terminal of the first pull off transistor; and an emitter terminal connected to the reference voltage (GND). 8. The lighting driver as claimed in claim 7 , wherein the interface circuit comprises: a control transistor which is turned on by an input voltage at the driver input and which pulls off the bias voltage at the base terminal of the first pull off transistor when the control transistor is turned on. 9. The lighting driver as claimed in claim 7 , wherein the correction circuit comprises: a delay circuit adapted to: pull off the bias voltage at the base terminal of the first pull off transistor when the shunt control signal does operate and up to said time delay after the end of the operation of the shunt control signal; and allow the bias voltage at the base terminal of the first pull off transistor to be pulled on after said time delay after the end of operating state of the shunt control signal. 10. The lighting driver as claimed in claim 9 , wherein the delay circuit comprises a transistor with an RC circuit connected to the shunt control signal, adapted to allow the bias voltage at the base terminal of the first pull off transistor to be pulled on only after said time delay. 11. The lighting driver as claimed in claim 1 , wherein the controller further comprises: a dimming interface adapted to receive a dimming level; and said controller is adapted to control a length of a duration of operating the shunt device according to said dimming level. 12. The lighting driver as claimed in claim 11 , wherein the controller further comprises: a feedback loop adapted to detect the current going to the lighting load and to control the length of the duration of operating the shunt device according to said diming level and said detected current, and the driver input is adapted to receive a power supply from an electronic high frequency fluorescent lighting ballast. 13. A lighting device comprising: the lighting driver as claimed in claim 1 ; and an LED lighting load to be driven by said lighting driver. 14. A lighting device as claimed in claim 11 , wherein the lighting load is a tubular LED lamp. 15. A method of controlling a lighting load, comprising: receiving an alternating current power supply from a fluorescent lighting ballast; controlling a shunt device for selectively shunting the power supply thereby to implement dimming control, by operating the shunt device and not operating the shunt device; operating the shunt device during a portion of a cycle of the alternating current power supply, such that a current is delivered to the lighting load only during the portion of the cycle of the alternating current power supply when the shunt device is not operated; and generating a detection signal and providing a detection feedback signal to a controller to start to operate the shunt device,