LED driver and LED lamp using the same

What we claim is: 1. An LED driver, comprising: a main circuit comprising a front-end stage configured to receive an AC input voltage and output a DC bus voltage, and a back-end stage; and a controller configured to receive a dimming signal, via an external source, for dimming an LED load and use a current hysteresis control in accordance with the dimming signal to generate a control signal, wherein the back-end stage is configured to receive the DC bus voltage and responsive to the control signal, output a desired drive current through output terminals to the LED load so as to produce a target illumination intensity; wherein a hysteresis width of the current hysteresis control varies with the dimming signal such that one of: an average value of an inductor current gradually reduces and a difference between the peak-to-peak values of the inductor current gradually decreases, or an average value of the inductor current gradually reduces as the dimming signal is reduced, and a difference between peak-to-peak values of the inductor current changes stepwise as the hysteresis width changes. 2. The LED driver as claimed in claim 1 , wherein the back-end stage comprises a controllable switch, the control signal is provided to the controllable switch to switch on or switch off the controllable switch, so that the desired drive current varies within the hysteresis width. 3. The LED driver as claimed in claim 2 , wherein the controller comprises a first module and a second module and the back-end stage further comprises an inductor; wherein the first module is configured to determine an upper limit current and a lower limit current of the current hysteresis control based on the dimming signal; and wherein the second module is configured to detect an inductor current flowing through the inductor and switch on or switch off the controllable switch based on the detected inductor current, when the inductor current reaches the upper limit current, the controllable switch is switched off and when the inductor current reaches the lower limit current, the controllable switch is switched on. 4. The LED driver as claimed in claim 2 , wherein the controller comprises a first module, a second module and an auxiliary circuit, wherein the first module is configured to receive the dimming signal and generate an upper limit current according to the dimming signal; wherein the auxiliary circuit comprises an auxiliary capacitor and an auxiliary resistor, one terminal of the auxiliary capacitor is grounded and the other terminal of the auxiliary capacitor is connected with one terminal of the auxiliary resistor, the other terminal of the auxiliary resistor is connected with a positive terminal of the output terminals, and the other terminal of the auxiliary capacitor is connected to the second module so as to provide a capacitor voltage of the auxiliary capacitor to the second module; and wherein the second module is configured to detect a switch current flowing through the controllable switch and switch on or switch off the controllable switch based on the detected switch current, when the switch current reaches the upper limit current, the controllable switch is switched off, and when the capacitor voltage reaches a threshold voltage, the controllable switch is switched on; and wherein the hysteresis width is determined by a charging time required by the auxiliary capacitor charged from zero voltage to the threshold voltage. 5. The LED driver as claimed in claim 4 , wherein the first module is further configured to produce the threshold voltage based on the dimming signal and provide the threshold voltage to the second module. 6. The LED driver as claimed in claim 4 , wherein the auxiliary circuit further comprises a transistor connected in series between the auxiliary resistor and the auxiliary capacitor; wherein the first module is further configured to provide an auxiliary control signal according to the dimming signal to a base electrode of the transistor for changing an equivalent resistance of the transistor, and the charging time of the auxiliary capacitor is adjusted by the equivalent resistance of the transistor. 7. The LED driver as claimed in claim 4 , wherein the auxiliary circuit further comprises a second controllable switch connected in series between the auxiliary resistor and the auxiliary capacitor; wherein the first module is further configured to provide an auxiliary control signal according to the dimming signal to a control electrode of the second controllable switch (for changing an average charging current of the auxiliary capacitor, and the charging time of the auxiliary capacitor is adjusted by the average charging current of the auxiliary capacitor. 8. The LED driver as claimed in claim 4 , wherein the hysteresis width has a first hysteresis width and a second hysteresis width, and the first hysteresis width is larger than the second hysteresis width, and the auxiliary circuit further comprises a branch for changing a charging current of the auxiliary capacitor based on the received dimming signal, so that the auxiliary capacitor has a first charging time and a second charging time; and wherein when the dimming signal is above a predetermined value, the auxiliary capacitor has the first charging time and the first hysteresis width is generated; when the dimming signal is below the predetermined value, the auxiliary capacitor has the second charging time and the second hysteresis width is generated. 9. The LED driver as claimed in claim 8 , wherein the branch is connected in parallel with the auxiliary capacitor and comprises a third controllable switch and a third auxiliary capacitor connected in series with the third controllable switch; wherein the first module is further configured to provide an auxiliary control signal according to the dimming signal to a control electrode of the third controllable switch; and wherein when the dimming signal is above the predetermined value, the third controllable switch is switched on and the auxiliary capacitor has the first charging time; when the dimming signal is below the predetermined value, the third controllable switch is switched off, and the auxiliary capacitor has the second charging time. 10. An LED lamp for connecting to an external power supply, comprising: an LED load including a plurality of LEDs; and an LED driver configured for driving the LED load, the LED driver comprising: a main circuit comprising a front-end stage configured to receive an AC input voltage and output a DC bus voltage, and a back-end stage; and a controller configured to receive a dimming signal, via an external source, for dimming an LED load and use a current hysteresis control in accordance with the dimming signal to generate a control signal, wherein the back-end stage is configured to receive the DC bus voltage and responsive to the control signal, output a desired drive current through output terminals to the LED load so as to produce a target illumination intensity, wherein a hysteresis width of the current hysteresis control varies with the dimming signal such that one of: an average value of an inductor current gradually reduces and a difference between the peak-to-peak values of the inductor current gradually decreases, or an average value of the inductor current gradually reduces as the dimming signal is reduced, and a difference between peak-to-peak values of the inductor current changes stepwise as the hysteresis width changes.