Hand-held, massively-parallel, bio-optoelectronic instrument

The invention claimed is: 1. A bioanalytic instrument comprising: a pulsed optical light source having a laser diode to produce a beam of optical pulses; a chip receptacle adapted to receive a packaged bio-optoelectronic chip; a beam-steering assembly adapted to steer the beam of optical pulses from the pulsed optical light source to the packaged bio-optoelectronic chip, the beam steering assembly including movable members; an alignment structure physically supporting each of the pulsed optical light source, the chip receptacle, and beam steering assembly; and a printed circuit board, registered to the alignment structure, on which the laser diode is mounted, and on which are also located a motion sensor which senses motion of the movable members in the beam-steering assembly; wherein the motion sensor includes an inductive motion sensor that senses inductive changes of the moveable members. 2. The bioanalytic instrument of claim 1 , wherein at least one enclosing wall dissipates heat generated within the bioanalytic instrument. 3. The bioanalytic instrument of claim 1 , wherein at least one enclosing wall guides or blocks forced air flow within the bioanalytic instrument. 4. The bioanalytic instrument of claim 1 , wherein the bioanalytic instrument weighs no more than three kilograms. 5. The bioanalytic instrument of claim 1 , wherein the bioanalytic instrument has a maximum length of no longer than 25 centimeters. 6. The bioanalytic instrument of claim 1 , wherein the alignment structure comprises a registration platform to which the pulsed optical source and beam-steering assembly are registered, and further comprising at least one optical component mounted to the registration platform that operates on the beam of optical pulses. 7. The bioanalytic instrument of claim 6 , wherein the packaged bio-optoelectronic chip and at least one optical component register to a first surface of the registration platform and the pulsed optical source and beam-steering assembly register to a second surface of the registration platform that is opposite the first surface. 8. The bioanalytic instrument of claim 7 , further comprising kinematic recesses formed in the second surface of the registration platform, wherein the beam-steering assembly self aligns to the registration platform via the kinematic recesses. 9. The bioanalytic instrument of claim 6 , wherein the alignment structure includes walls or reinforcing ribs that stiffen the registration platform. 10. The bioanalytic instrument of claim 1 , wherein the printed circuit control board forms the majority of a wall of a chamber within the bioanalytic instrument. 11. The bioanalytic instrument of claim 10 , wherein the printed circuit control board confines a majority of forced air flow within the bioanalytic instrument to the chamber. 12. The bioanalytic instrument of claim 11 , further comprising: a thermal post located adjacent to the chip receptacle and arranged to convey heat from the packaged bio-optoelectronic chip toward the chamber; and a heat dissipating element located in the chamber and thermally coupled to the thermal post. 13. The bioanalytic instrument of claim 11 , further comprising: a thermally conductive reinforcing element attached to the printed circuit board and arranged to convey heat from the pulsed optical source toward the chamber; and a heat dissipating element located in the chamber and thermally coupled to the thermally conductive reinforcing element. 14. The bioanalytic instrument of claim 11 , further comprising at least one battery located in the chamber. 15. The bioanalytic instrument of claim 1 , wherein the pulsed optical light source comprises: a driving circuit for the laser diode formed on the printed circuit board, wherein the pulsed printed circuit board attaches directly to the beam-steering assembly. 16. The bioanalytic instrument of claim 1 , further comprising conductive elements mounted to the moveable members in the beam-steering assembly. 17. The bioanalytic instrument of claim 16 , further comprising: a collecting lens mounted to the printed circuit board; and two or more voice coils mounted to the printed circuit board, wherein the two or more voice coils are configured to activate the moveable members in the beam-steering assembly. 18. The bioanalytic instrument of claim 15 , further comprising a board reinforcing element attached to the pulsed source circuit board that stiffens the pulsed source board. 19. The bioanalytic instrument of claim 18 , wherein the board reinforcing element thermally couples to a heat dissipating element. 20. The bioanalytic instrument of claim 15 , wherein the driving circuit comprises: a pulse-generating circuit configured to produce unipolar pulses; and a diode-driving circuit that outputs an electrical pulse to control the laser diode. 21. The bioanalytic instrument of claim 20 , wherein the pulse-generating circuit comprises a logic gate configured to receive differential clock signals and output the unipolar pulses. 22. The bioanalytic instrument of claim 20 , wherein the diode-driving circuit comprises: a first transistor connected as a common source amplifier and arranged to receive the unipolar pulses from the pulse-generating circuit; and a second transistor connected as a source follower and arranged to receive an output from the common source amplifier. 23. The bioanalytic instrument of claim 22 , wherein the first transistor and second transistor are high-electron-mobility transistors. 24. The bioanalytic instrument of claim 22 , further comprising an inductor connected between a drain of the first transistor and a voltage supply for the first transistor. 25. The bioanalytic instrument of claim 20 , wherein the diode-driving circuit comprises: a field-effect transistor connected between a cathode of the laser diode and a reference potential; an inductor and resistor connected in series between an anode and the cathode of the laser diode; and a capacitor connected between the anode and the reference potential. 26. The bioanalytic instrument of claim 25 , wherein the diode-driving circuit causes the laser diode to output an optical pulse on average having a temporal full-width half-maximum value between 40 ps and 250 ps in response to application of a unipolar pulse of the unipolar pulses to a gate of the field-effect transistor. 27. The bioanalytic instrument of claim 26 , wherein the diode-driving circuit causes the laser diode to output the optical pulse such that an intensity of the pulse reduces by no less than 40 dB by at most 600 ps from a peak value of the optical pulse. 28. The bioanalytic instrument of claim 1 , wherein the beam-steering assembly further includes a gimbal, and wherein the moveable members includes a lens; wherein the gimbal supports and rotates the lens about two axes to laterally translate the beam passing through the lens. 29. The bioanalytic instrument of claim 1 , further comprising: a first lens mounted adjacent to the pulsed optical source; a second lens mounted in a moveable component of the beam-steering assembly; and a third lens arranged to focus a beam from the second lens onto an optical coupler on the bio-optoelectronic chip. 30. The bioanalytic instrument of claim 29 , wherein the first lens, the second lens, a