Methods and Apparatus for Pipetting

What is claimed is: 1 . A pipette that comprises: (a) a set of multiple cylinders, in which each cylinder has a diameter that is different than the diameter of each other cylinder; (b) multiple pistons; (c) a shaft that is configured to move the multiple pistons simultaneously, such that each piston moves within a cylinder, and (d) a selection mechanism for selecting which cylinder is connected by an airway to a pipette tip and which other cylinders are connected by an airway to ambient atmosphere by a path that does not pass through a pipette tip. 2 . The pipette of claim 1 , wherein: (a) the cylinders are configured to contain air; and (b) the pipette is configured such that, when the pistons move down, the volume of air displaced from each cylinder is different than the volume of air displaced from each other cylinder. 3 . The pipette of claim 1 , wherein the selection mechanism is configured to be positioned in a set of discrete positions, such that: (a) at all of the discrete positions, the multiple cylinders are connected to a set of multiple airways, one airway per cylinder; and (b) which cylinder is connected to which airway varies from position to position in the set of discrete positions. 4 . The pipette of claim 3 , wherein at each different position in the set of discrete positions, only one cylinder in the pipette is connected by an airway to a pipette tip. 5 . The pipette of claim 3 , wherein at each different position in the set of discrete positions: (a) each airway, in the set of airways, has a different minimum cross-sectional area than the minimum cross-sectional area of any other airway in the set of airways; and (b) when the pistons move down, the different minimum cross-sectional areas of the airways tend to equalize air pressure in the multiple cylinders. 6 . The pipette of claim 1 , wherein the pipette includes a linkage system that, when the pistons move down, transmits force from the shaft to the multiple pistons, in such a manner that the force is distributed unequally among the multiple pistons. 7 . The pipette of claim 1 , wherein: (a) the pipette system includes a linkage system for transmitting force from the shaft to the pistons; (b) the linkage system includes spokes of unequal lengths, each spoke being attached to the shaft and to a piston; (c) when the shaft moves down, each respective piston applies a torque against the spoke to which the respective piston is attached; and (d) the lengths of the spokes are such that, when the shaft moves down, the magnitudes of the torques applied by the respective pistons are substantially equal to each other. 8 . The pipette of claim 1 , wherein: (a) the pipette system includes concentric rings for transmitting force to the multiple pistons; and (b) when the shaft moves down (i) each ring transmits force to only one of the pistons, and (ii) the concentric rings, taken together, transmit force from the shaft to all of the pistons. 9 . The pipette of claim 1 , wherein the pipette includes a plunger that is configured to be moved by force applied by a user's finger, such that the plunger in turn actuates movement of the pistons. 10 . The pipette of claim 9 , wherein the pipette includes one or more sensors for gathering sensor data indicative of speed of a piston. 11 . The pipette of claim 10 , wherein the pipette is configured to output the sensor data to a computer that is programmed to calculate, based on the sensor data, one or more shear forces. 12 . A system comprising: (a) a pipette that includes (i) multiple cylinders, wherein each cylinder has a minimum cross-sectional area that is different than the minimum cross-sectional area of each other cylinder, (ii) multiple pistons, and (iii) a shaft that is configured to move the multiple pistons; (b) a camera for capturing images of a well tray and of a pipette tip that is attached to the pipette; and (c) one or more computers programmed (i) to calculate, based on the images, position of the pipette tip at different times, and (ii) to identify and record multiple events, wherein each event comprises the pipette dispensing liquid into a specific well in the well tray at a specific time. 13 . The system of claim 12 , wherein the one or more computers are programmed to calculate, based on the images, volume of liquid in wells in the well tray. 14 . The system of claim 12 , wherein the system includes one or more I/O devices for accepting input from a user, which input comprises annotations regarding one or more pipetting events. 15 . The system of claim 12 , wherein: (a) the system includes one or more sensors, in addition to the camera, for gathering sensor data; and (b) the one or more computers are programmed to compute, based on the sensor data, an adjustment to the pipette. 16 . The system of claim 12 , wherein: (a) the system includes a pressure sensor for gathering sensor data indicative of pressure exerted by a user's finger on a plunger of the pipette; and (b) the one or more computers are programmed to compute, based on the sensor data indicative of pressure, an adjustment to the pipette, which adjustment controls amount of work performed when moving the shaft down. 17 . A method comprising a single shaft of a pipette moving downward, and thereby causing multiple pistons of the pipette to move downward simultaneously in multiple cylinders of the pipette; wherein the pipette includes a selection mechanism for selecting which cylinder is connected by an airway to a pipette tip and which other cylinders are connected by an airway to ambient atmosphere by a path that does not pass through a pipette tip. 18 . The method of claim 17 , wherein the method further comprises (a) a camera capturing images of a well tray and of a pipette tip; and (b) one or more computers (i) calculating, based on the images, position of the pipette tip at different times, and (ii) identifying and recording multiple events, wherein each event comprises the pipette dispensing liquid into a specific well in the well tray at a specific time. 19 . The method of claim 17 , wherein the one or more computers are programmed to calculate, based on the images, volume of liquid in wells in the well tray. 20 . The method of claim 17 , wherein the method includes (a) one or more sensors, in addition to the camera, gathering sensor data; and (b) one or more computers computing, based on the sensor data, an adjustment to the pipette.