Integrated device and method for driving lighting loads with a brightness compensation

What is claimed is: 1. An integrated device for driving a lighting load, the integrated device comprising: a first memory element configured to store a nominal duty-cycle at a nominal supply voltage; an actual voltage acquisition element configured to detect an actual supply voltage; a processing unit coupled to the first memory element and to the actual voltage acquisition element, the processing unit configured to calculate a voltage compensated duty-cycle; a driver unit coupled to the processing unit and configured to be supplied according to the voltage compensated duty-cycle; a second memory element coupled to the processing unit and configured to store the voltage compensated duty-cycle; and a third memory element coupled to the processing unit, the third memory element configured to store a load characteristic value; wherein the processing unit is configured to calculate a voltage compensated duty-cycle DC C according to equation: DC C = V th - V LED V B - V LED ⁢ DC n wherein DC N is the nominal duty-cycle, V TH is the nominal supply voltage, V LED is the load characteristic value, and V B is the actual supply voltage. 2. The integrated device according to claim 1 , wherein the load characteristic value comprises a load voltage drop. 3. The integrated device according to claim 1 , further comprising a plurality of load terminals coupled to the driver unit and configured to be coupled to a plurality of lighting loads, the driver unit comprising a plurality of driver elements, each driver element being coupled to a respective load terminal. 4. The integrated device according to claim 3 , wherein the first memory element comprises a plurality of nominal duty-cycle registers, each nominal duty-cycle register being associated to a respective drive element and a respective load terminal. 5. The integrated device according to claim 3 , further comprising a plurality of characteristics registers, each characteristics register being associated to a respective drive element and a respective load terminal. 6. The integrated device according to claim 3 , further comprising an adjustment activation memory configured to store an activation bit indicative of whether brightness of the lighting load is to be compensated for supply voltage. 7. The integrated device according to claim 6 , wherein the adjustment activation memory comprises a plurality of adjustment activation memory elements, each adjustment activation memory element being associated to a respective driver and a respective load terminal. 8. The integrated device according to claim 1 , wherein the integrated device further comprises a plurality of load terminals coupled to the driver unit and configured to be coupled to a plurality of lighting loads, the driver unit comprising a plurality of driver elements, each driver element being coupled to a respective load terminal; wherein the first memory element comprises a plurality of nominal duty-cycle registers, each nominal duty-cycle register being associated to a respective drive element and a respective load terminal; wherein the integrated device further comprises a plurality of characteristics registers, each characteristics register being associated to a respective drive element and a respective load terminal; wherein the integrated device further comprises an adjustment activation memory configured to store an activation bit indicative of whether brightness of the lighting load is to be compensated for supply voltage; and wherein the adjustment activation memory comprises a plurality of adjustment activation memory elements, each adjustment activation memory element being associated to a respective driver and a respective load terminal. 9. The integrated device according to claim 1 , wherein the first memory element and the third memory element are configured to be coupled to a microcontroller through an SPI bus. 10. The integrated device according to claim 1 , wherein the actual voltage acquisition element comprises an AD converter configured to be coupled to a power supply. 11. The integrated device according to claim 1 , wherein the processing unit comprises a state machine implemented as hardwired logic. 12. An integrated device for driving a lighting load, the integrated device comprising: a supply voltage node; an analog-to-digital converter with an analog input coupled to the supply voltage node; a nominal duty cycle register that stores a nominal duty-cycle at a nominal supply voltage; a hardwired logic circuit coupled to a digital output of the analog-to-digital converter and to the nominal duty cycle register, the hardwired logic circuit configured to implement a state machine to calculate a voltage compensated duty-cycle; a characteristic register coupled to the hardwired logic circuit and configured to store a load voltage drop; a compensated duty-cycle register coupled to the hardwired logic circuit to store the voltage compensated duty-cycle; a driver element coupled to the supply voltage node and the compensated duty-cycle register; and a load terminal configured to be connected to a lighting load; wherein the integrated device is configured to calculate the voltage compensated duty-cycle DC C according to equation: DC C = V th - V LED V B - V LED ⁢ DC n wherein DC N is the nominal duty-cycle, V TH is the nominal supply voltage, V LED is a load characteristic value, and V B is an actual supply voltage. 13. The integrated device according to claim 12 , wherein the integrated device comprises a plurality of load terminals and a plurality of driver elements, each driver element configured to be coupled to an associated lighting load via a respective load terminal. 14. The integrated device according to claim 13 , wherein the integrated device comprises a plurality of nominal duty-cycle registers, each nominal duty-cycle register being associated with a respective drive element and a respective load terminal. 15. The integrated device acc