Raman spectrometer

The invention claimed is: 1. A method of measuring Raman spectral features of a sample onto which ambient light is incident, comprising: defining, on a charge coupled device (CCD) having a plurality of pixels, detection pixels, and storage pixels separate from the detection pixels; providing a laser light source arranged to direct laser probe light to the sample; providing collection optics arranged to direct light scattered from the sample to the detection pixels; for the duration of an exposure period, repeating a cycle of at least a first interval during which background light from the sample, but not laser probe light, is received at the detection pixels for the accumulation of first, background, spectral signals at those pixels, and a second interval during which both background light from the sample and laser probe light Raman scattered by the sample is received at the detection pixels for the accumulation of second, Raman, spectral signals at those pixels; during the first intervals, further accumulating the first, background, spectral signals in the detection pixels, while storing the accumulated second, Raman, spectral signals in said storage pixels; during the second intervals, further accumulating the second, Raman, spectral signals in the detection pixels, while storing the accumulated first, background, spectral signals in said storage pixels, wherein the background light from the sample comprises ambient light scattered by the sample. 2. The method of claim 1 wherein the laser probe light is incident on the sample during each second interval and is absent from the sample during each first interval. 3. The method of claim 2 wherein the laser light source is operated to emit said laser probe light only during each said second interval, and not during each first interval. 4. A method of measuring Raman spectral features of a sample, comprising: defining, on a charge coupled device (CCD) having a plurality of pixels, detection pixels, and storage pixels separate from the detection pixels; providing a laser light source arranged to direct laser probe light of multiple different wavelengths to the sample; providing collection optics arranged to direct light scattered from the sample to the detection pixels; for the duration of an exposure period, repeating a cycle of at least a first interval during which both background light from the sample, and laser probe light of a first wavelength scattered by the sample, are received at the detection pixels for the accumulation of first, Raman, spectral signals at those pixels, and a second interval during which both background light from the sample, and laser probe light of a second wavelength scattered by the sample, the second wavelength being different to the first wavelength, are received at the detection pixels for the accumulation of second, Raman, spectral signals at those pixels; during the first intervals, further accumulating the first, Raman, spectral signals in the detection pixels, while storing the accumulated second, Raman, spectral signals in said storage pixels; during the second intervals, further accumulating the second, Raman, spectral signals in the detection pixels, while storing the accumulated first, Raman, spectral signals in said storage pixels. 5. The method of claim 4 wherein the cycle further comprises at least a third interval during which both background light from the sample, and laser probe light of a third wavelength scattered by the sample, are received at the detection pixels for the accumulation of third, Raman, spectral signals at those pixels, the method further comprising: during the first and second intervals, storing the accumulated third, Raman, spectral signals in the storage pixels; and during the third intervals, further accumulating the third, Raman, spectral signals in the detection pixels, while storing the accumulated first and second, Raman, spectral signals in the storage pixels. 6. The method of claim 4 wherein: the cycle further comprises at least a further interval during which background light from the sample, but not laser probe light scattered by the sample, is received at the detection pixels for the accumulation of further, background spectral signals at those pixels, the method further comprising: during the first and second intervals, storing the accumulated further, background spectral signals in the storage pixels; and during the further intervals, further accumulating the further, background spectral signals in the detection pixels, while storing the accumulated first and second, Raman, spectral signals in the storage pixels. 7. The method of claim 4 wherein the background light from the sample which is received during intervals when scattered laser probe light is also received from the sample comprises fluorescence of the sample. 8. The method of claim 4 wherein the fluorescence of the sample is emitted responsive to the laser probe light incident on the sample. 9. The method of claim 4 wherein the background light from the sample comprises ambient light incident on and scattered by the sample. 10. The method of claim 4 further comprising: after the exposure period, reading from the CCD the spectral signals accumulated during the exposure period; and calculating compensated Raman spectral signals, compensated to remove signals of the background light, using the read accumulated spectral signals from one or more such exposure periods. 11. The method of claim 10 further comprising determining a chemical characteristic of the sample from the compensated Raman spectral signals from one or more exposure periods. 12. The method of claim 4 wherein the collection optics comprises a spectrometer arranged to spectrally disperse the light scattered from the sample across the detection pixels. 13. The method of claim 4 wherein the method is carried out by a hand held device. 14. The method of claim 4 wherein the repeated cycle further comprises a further interval during which laser probe light scattered by a reference sample is received at the detection pixels for the accumulation of reference spectral signals. 15. The method of claim 4 , wherein the spectral signals are moved between the detection pixels and the storage pixels by row shifting charge contents of the pixels of the CCD. 16. The method of claim 4 wherein the storage pixels comprise at least first and second groups of storage pixels disposed on opposing sides of the detection pixels, the first group being used for storage of the accumulated first, background or Raman, spectral signals, and the second group being used for storage of the accumulated second, Raman, signals. 17. The method of claim 4 wherein: the storage pixels comprise at least first and second groups of storage pixels disposed on opposing sides of the detection pixels; during a first exposure period using the first group for storage of the accumulated first, background or Raman, spectral signals, and using the second group for storage of the accumulated second, Raman, spectral signals; during a second exposure period using the first group for storage of the accumulated second, Raman, spectral signals, and using the second group for storage of the accumulated first, background, spectral signals. 18. The method of claim 17 comprising: reading the accumulated first and second spectral signals from the CCD at the end of each of the first and second exposure periods; combining together the accumulated first spectral signals from both exposure periods; combining together the accumulated seco