Accurate photo detector measurements for LIDAR

What is claimed is: 1. A method of performing ranging using a light ranging system, the method comprising: transmitting N pulse trains from a light source as part of a ranging measurement, each of the N pulse trains including one or more pulses from the light source and corresponding to a different time interval that is triggered by a start signal, wherein the N pulse trains reflect from an object, and wherein N is an integer greater than one; detecting photons of the N pulse trains by a photosensor of a pixel of the light ranging system, thereby generating data values at a plurality of time points; determining a histogram corresponding to the data values in a plurality of time bins, wherein a counter of the histogram at a particular time bin corresponds to one or more data values at one or more time points within the particular time bin, wherein the N pulse trains have varying offsets from each other, and wherein at least two of the N pulse trains are offset by less than a width of a time bin; determining a received time corresponding to the N pulse trains relative to the start signal; and determining a distance to the object using the received time. 2. The method of claim 1 , wherein each of the N pulse trains have a same pattern of one or more pulses. 3. The method of claim 1 , wherein the N pulse trains are all of the pulse trains of the ranging measurement. 4. The method of claim 1 , wherein successive pulse trains of the N pulse trains are offset by a time offset T. 5. The method of claim 4 , wherein N multiplied by the time offset T is equal to the width of a time bin. 6. The method of claim 4 , wherein determining the received time includes: applying a matched filter to the histogram to obtain a filtered histogram; and determining the received time using a maximum value of the filtered histogram and the time offset T. 7. The method of claim 6 , wherein the time offset T is between 0.5 and 0.01 of the width of the time bin. 8. The method of claim 7 , wherein the time offset T is 0.1 of the width of the time bin. 9. A light ranging system comprising: one or more processors; and a computer readable medium storing a plurality of instructions, executable by the one or more processors to perform operations comprising: transmitting N pulse trains from a light source as part of a ranging measurement, each of the N pulse trains including one or more pulses from the light source and corresponding to a different time interval that is triggered by a start signal, wherein the N pulse trains reflect from an object, and wherein N is an integer greater than one; detecting photons of the N pulse trains by a photosensor of a pixel of the light ranging system, thereby generating data values at a plurality of time points; determining a histogram corresponding to the data values in a plurality of time bins, wherein a counter of the histogram at a particular time bin corresponds to one or more data values at one or more time points within the particular time bin, wherein the N pulse trains have varying offsets from each other, and wherein at least two of the N pulse trains are offset by less than a width of a time bin; determining a received time corresponding to the N pulse trains relative to the start signal; and determining a distance to the object using the received time. 10. The light ranging system of claim 9 , wherein each of the N pulse trains have a same pattern of one or more pulses. 11. The light ranging system of claim 9 , wherein the N pulse trains are all of the pulse trains of the ranging measurement. 12. The light ranging system of claim 9 , wherein successive pulse trains of the N pulse trains are offset by a time offset T. 13. The light ranging system of claim 12 , wherein N multiplied by the time offset T is equal to the width of a time bin. 14. The light ranging system of claim 12 , wherein determining the received time includes: applying a matched filter to the histogram to obtain a filtered histogram; and determining the received time using a maximum value of the filtered histogram and the time offset T. 15. A computer product comprising a computer readable medium storing a plurality of instructions for controlling a computer system to perform operations comprising: transmitting N pulse trains from a light source as part of a ranging measurement, each of the N pulse trains including one or more pulses from the light source and corresponding to a different time interval that is triggered by a start signal, wherein the N pulse trains reflect from an object, and wherein N is an integer greater than one; detecting photons of the N pulse trains by a photosensor of a pixel of the light ranging system, thereby generating data values at a plurality of time points; determining a histogram corresponding to the data values in a plurality of time bins, wherein a counter of the histogram at a particular time bin corresponds to one or more data values at one or more time points within the particular time bin, wherein the N pulse trains have varying offsets from each other, and wherein at least two of the N pulse trains are offset by less than a width of a time bin; determining a received time corresponding to the N pulse trains relative to the start signal; and determining a distance to the object using the received time. 16. The computer product of claim 15 , wherein each of the N pulse trains have a same pattern of one or more pulses. 17. The computer product of claim 15 , wherein the N pulse trains are all of the pulse trains of the ranging measurement. 18. The computer product of claim 15 , wherein successive pulse trains of the N pulse trains are offset by a time offset T. 19. The computer product of claim 18 , wherein N multiplied by the time offset T is equal to the width of a time bin. 20. The computer product of claim 18 , wherein determining the received time includes: applying a matched filter to the histogram to obtain a filtered histogram; and determining the received time using a maximum value of the filtered histogram and the time offset T.