Method for sensing ambient light in a display

The invention claimed is: 1. A method for sensing light, comprising: receiving light in a light sensitive element and generating a signal indicative of an amount of light received by generating a stream of pulses of which a temporal density of the pulses is indicative of the amount of light received; operating a display with at least one sub-frame having a duty cycle to display information with a brightness dependent on the duty cycle, wherein the duty cycle includes a first portion in which the display is operated to emit light and a second portion in which the display is operated not to emit light; counting of the pulses generated during the at least one sub-frame; another counting of the pulses generated during an observation window, wherein the observation window is determined in dependence on the duty cycle such that when the duty cycle has a first rate lower than a predetermined rate, the observation window is determined to be active during the first portion of the duty cycle, and when the duty cycle has a second rate higher than the predetermined rate, the observation window is determined to be active during the second portion of the duty cycle; and calculating a value indicating an amount of received ambient light from the counting of the pulses and the other counting of the pulses. 2. The method according to claim 1 , wherein, when the duty cycle has the first rate, the observation window is determined to be active during the first portion of the duty cycle and at least one margin, and when the duty cycle has the second rate, the observation window is determined to be active during the second portion of the duty cycle and at least one margin. 3. The method according to claim 2 , wherein the at least one margin includes at least one of the transitional time during which the signal indicates a transition from a higher amount of light to a lower amount of light received and another transitional time during which the signal indicates the transition from a lower amount of light to a higher amount of light received. 4. The method according to claim 2 , wherein, when the duty cycle has the first rate, the observation window is determined to include a first margin including the transitional time from a lower density of pulses to a higher density of pulses and a second margin including the transitional time from a higher density of pulses to a lower density of pulses, when the duty cycle has the second rate, the observation window is determined to include a third margin including the transitional time from a higher density of pulses to a lower density of pulses and a fourth margin including the transitional time from a lower density of pulses to a higher density of pulses. 5. The method according to claim 4 , wherein generating a signal indicative of the amount of light received comprises generating a current in a photosensitive element and generating the stream of pulses by a sigma-delta modulation process. 6. The method according to claim 5 , wherein generating the stream of pulses by a sigma-delta modulation process comprises: integrating the current in a capacitive element; generating a pulse, when the charge stored in the capacitive element exceeds a threshold; then subtracting a predetermined amount of charge from the charge stored in the capacitive element and continuing to integrate the current in the capacitive element. 7. The method according to claim 5 , wherein, when the duty cycle of the operating of the display in response to a pulse width modulation signal is lower than the predetermined rate, a step of calculating a value DLP indicating the amount of received light from the displaying of information comprises: counting the pulses during the observation window as OWP; counting the pulses during the sub-frame as ALLP; calculating DLP =( OWP−ALLP*OW )/(1− OW ), wherein OW represents the duty cycle of the observation window. 8. The method according to claim 7 , wherein a step of calculating a value ALP indicating the amount of received ambient light comprises calculating: ALP=ALLP −( OWP—ALLP*OW )/(1− OW ) or ALP=ALLP−DLP. 9. The method according to claim 5 wherein, when the duty cycle of the operating of the display in response to a pulse width modulation signal is higher than the predetermined rate, a step of calculating a value DLP indicating the amount of received light from the displaying of information comprises: counting the pulses during the observation window as OWP; counting the pulses during the sub-frame as ALLP; calculating DLP =( ALLP*OW*DC−OWP*DC )/( OW*DC +(1− DC )− OW ), wherein OW represents the duty cycle of the observation window and DC represents the duty cycle of the operating of the display. 10. The method according to claim 9 , wherein a step of calculating a value ALP indicating the amount of received ambient light comprises calculating: ALP=ALLP −( ALLP*OW*DC−OWP*DC )/( OW*DC +(1− DC )− OW ) or ALP=ALLP−DLP. 11. The method according claim 5 , comprising counting the pulses during a multitude of sub-frames and counting the pulses during a multitude of observation windows occurring within the multitude of sub-frames to reduce ambient light modulation caused by the mains frequency. 12. The method according to claim 11 , wherein operating a display comprises displaying information within multiple picture frames, each frame including two or more sub-frames, wherein the counting of the pulses during a multitude of sub-frames starts with the second or a later occurring sub-frame of the first one of the multiple picture frames, and wherein the counting of the pulses during a multitude of observation windows ends with the first or a later occurring sub-frame of the last one of the multiple picture frames. 13. The method according to claim 2 , wherein the predetermined rate of the duty cycle is 50%. 14. The method according to claim 1 , comprising sensing the light during a multitude of sub-frames and sensing the light during a multitude of observation windows occurring within the multitude of sub-frames to reduce ambient light modulation caused by the mains frequency. 15. The method according to claim 1 , comprising: receiving light in a photoelectric element and performing a sigma delta modulation on the current generated by the photoelectric element to generate a stream of pulses indicative of the amount of light received; counting the pulses during at least one sub-frame when the duty cycle of operating the display during the at least one sub-frame is lower than 50%, then: counting the pulses during an observation window that includes an active portion of the duty cycle and a margin portion before and after the active portion; when the duty cycle of operating the display during the at least one sub-frame is higher than 50%, then: counting the pulses during an observation window that includes an inactive portion of the duty cycle and a margin portion before and after the inactive portion; continuing counting during a sub-frame and counting during a measurement window for several subsequent sub-frames, thereby adding the respective counts for the several subsequent sub-frames; performing a calculation using the counts from the sub-frames and the counts from the observations windows and the values for the duty cycle of the sub-frames and the duty cycle of the observation windows to achieve a value for the light received from the displaying of information and/or the ambient light received; adjusting the duty cycle of further occurring sub-frames to achieve an adjusted brightness of the displaying of informati