Robot and adaptive placement system and method

What is claimed is: 1. A method comprising: moving a substrate, located on a first end effector of a robot, from a first location towards a second location by the robot, where the second location is spaced from the first location; determining a location of a fiducial on the substrate while the substrate is being moved from the first location towards the second location, where the determining of the location of the fiducial occurs after the substrate leaves the first location and before the substrate reaches the second location, where the fiducial is on a planar side of the substrate spaced from an edge of the substrate, where the determining of the location of the fiducial on the substrate while the substrate is being moved comprises at least one sensor and/or at least one camera providing input to a controller to determine the location of the fiducial spaced from the edge of the substrate; comparing the determined location of the fiducial with a reference fiducial location while the robot is moving the substrate from the first location towards the second location, where the controller compares the determined location of the fiducial with the reference fiducial location, while the substrate is in a path between the first and second locations, to determine an offset of the substrate relative to a desired location of the substrate; and adjusting movement of the first end effector based upon the determined offset prior to moving the substrate into the second location. 2. A method as in claim 1 further comprising comparing the determined location of the fiducial relative to a fiducial on a second end effector of the robot while the second end effector is being moved in substantial unison with the first end effector. 3. A method as in claim 1 where the substrate is a first substrate, and further comprising determining an offset of a second substrate of a second end effector of the robot, based at least partially upon a fiducial on the second substrate, and adjusting movement of the first and second end effectors relative to each other while the substrates are moving and prior to the first substrate reaching the second location and prior to the second substrate reaching a different spaced second location. 4. A method as in claim 1 where the robot comprises a plurality of sets of end effectors, where the end effectors are connected to a drive by the movable arm assembly of the robot, where a first one of the sets of end effectors comprises at least two of the end effectors including the first end effector, where the drive and the movable arm assembly move the at least two end effectors substantially in unison from a retracted position towards an extended position towards two different respective target locations, and where the at least two end effectors at least partially independently move relative to each other on the moveable arm assembly, where a second one of the sets of end effectors comprises at least two other of the end effectors, where the drive and the movable arm assembly move the at least two other end effectors substantially in unison from the retracted position towards the extended position towards the two different respective target locations, and where the at least two other end effectors at least partially independently move relative to each other on the moveable arm assembly based upon location of fiducials on the substrates as the robot moves the substrates and prior to reaching the target locations. 5. A method as in claim 1 where the controller, connected to the robot, adjusts movement of the end effector based, at least partially, upon the compared determined location versus the reference fiducial location. 6. An apparatus comprising: at least one processor; and and at least one non-transitory memory including computer program code, the at least one memory and the computer program code configured to, with the at least one processor, cause the apparatus to: determine a location of a fiducial on a substrate while the substrate is being moved from a first location towards a second location, where the location of the fiducial is determined after the substrate leaves the first location and before the substrate reaches the second location, where the fiducial is on a planar side of the substrate spaced from an edge of the substrate, where the second location is spaced from the first location, where the substrate is located on a first end effector of a robot, where the determination of the location of the fiducial spaced from the edge of the substrate occurs with use of at least one sensor and/or at least one camera providing input to the apparatus to determine the location of the fiducial spaced from the edge of the substrate; and compare the determined location of the fiducial with a reference fiducial location while the robot is moving the substrate from the first location towards the second location, where the apparatus compares the determined location of the fiducial with the reference fiducial location, while the substrate is in a path between the first and second locations, to determine an offset of the substrate relative to a desired location of the substrate; and adjusting movement of the first end effector based upon the determined offset prior to moving the substrate into the second location. 7. An apparatus as in claim 6 where the processor, memory and program code are configured to compare the determined location of the fiducial relative to a fiducial on a second end effector of the apparatus while the second end effector is being moved in substantial unison with the first end effector. 8. An apparatus as in claim 6 where the substrate is a first substrate, and where the processor, memory and program code are configured to determine an offset of a second substrate of a second end effector of the apparatus, based at least partially upon a fiducial on the second substrate, and adjust movement of the first and second end effectors relative to each other while the substrates are moving and prior to the first substrate reaching the second location and prior to the second substrate reaching a different spaced second location. 9. An apparatus as in claim 6 where the apparatus comprises a plurality of sets of end effectors, where the end effectors are connected to a drive by the movable arm assembly of the robot, where a first one of the sets of end effectors comprises at least two of the end effectors including the first end effector, where the drive and the movable arm assembly move the at least two end effectors substantially in unison from a retracted position towards an extended position towards two different respective target locations, and where the at least two end effectors at least partially independently move relative to each other on the moveable arm assembly, where a second one of the sets of end effectors comprises at least two other of the end effectors, where the drive and the movable arm assembly move the at least two other end effectors substantially in unison from the retracted position towards the extended position towards the two different respective target locations, and the processor, memory and program code are configured to at least partially independently move the at least two other end effectors relative to each other on the moveable arm assembly based upon location of fiducials on the substrates as the apparatus moves the substrates and prior to reaching the target locations. 10. An apparatus as in claim 6 where the processor, memory and program code are configured to adjust movement of the end effector based, at least partially, upon the compared determined location versus the reference fiducial location. 11. A non-transitory program storage device readable by