Patient support apparatus having motorized wheels

The invention claimed is: 1 . A patient support apparatus for propelling a patient along a floor, the patient support apparatus comprising a frame configured to support the patient, at least one dual-wheel motorized caster coupled to the frame and engaging the floor, the at least one dual-wheel motorized caster having first and second motors and first and second wheels coupled to the first and second motors, respectively, power drive circuitry coupled to the first and second motors of the at least one dual-wheel motorized caster to selectively drive the first and second motors to propel the patient support apparatus along the floor via rotation of the first and second wheels and to selectively swivel the at least one dual-wheel motorized caster about a caster swivel axis, and a joystick movable to provide an input command to the power drive circuitry regarding propulsion of the patient support apparatus, the joystick having a handle that is movable into a dead band zone to command the power drive circuitry to swivel the at least one dual-wheel motorized caster into a drive orientation corresponding to a drive direction of the patient support apparatus without propelling the patient support apparatus in the drive direction, the handle also being movable from the dead band zone into a drive zone to command the power drive circuitry to propel the patient support apparatus in the drive direction via rotation of the first and second wheels by the first and second motors, respectively. 2 . The patient support apparatus of claim 1 , wherein the joystick includes a first user input coupled to the handle and engageable by a user, wherein movement of the joystick into the dead band zone does not swivel the dual-wheel motorized caster unless the first user input is engaged by the user, and wherein movement of the joystick into the drive zone does not result rotation of the first and second wheels by the first and second motors, respectively, unless the first user input is engaged by the user. 3 . The patient support apparatus of claim 2 , wherein the first user input comprises a movable trigger. 4 . The patient support apparatus of claim 3 , wherein an upper portion of the handle overhangs the movable trigger. 5 . The patient support apparatus of claim 2 , wherein the joystick further includes a second user input coupled to the handle and engageable by a user to move from a first position to a second position; wherein when the second user input is in the first position and the drive direction is initially angled with respect to a longitudinal dimension of the patient support apparatus, the patient support apparatus is propelled in a manner that turns the patient support apparatus from an initial orientation into an orientation having the longitudinal dimension of the patient support apparatus parallel with the drive direction; and wherein when the second user input is in the second position and the drive direction is angled with respect to a longitudinal dimension of the patient support apparatus, the patient support apparatus is propelled in a manner that maintains the initial orientation of the patient support apparatus while the patient support apparatus is being propelled in the drive direction. 6 . The patient support apparatus of claim 1 , further comprising an accelerometer that provides an accelerometer signal to the power drive circuitry which senses how quickly the handle of the joystick is moved within the dead band zone to determine how quickly to swivel the dual-wheel motorized caster. 7 . The patient support apparatus of claim 6 , wherein the accelerometer signal is also used by the power drive circuitry to determine an acceleration profile to implement based on how quickly the handle of the joystick is moved within the drive zone. 8 . The patient support apparatus of claim 1 , wherein a speed at which the patient support apparatus is propelled is determined by the power circuitry based on how far into the drive zone the handle is moved. 9 . The patient support apparatus of claim 1 , wherein the power drive circuitry implements an exponential acceleration profile for propelling the patient support apparatus upon initial propulsion of the patient support apparatus in response to the handle of the joystick being moved into the drive zone. 10 . The patient support apparatus of claim 9 , wherein the power drive circuitry implements a linear deceleration profile in response to the joystick being moved into a neutral position within the dead band zone. 11 . The patient support apparatus of claim 1 , wherein after being propelled and coming to a stop, the dual-wheel motorized caster is left in the drive orientation that existed while the patient support apparatus was being propelled. 12 . The patient support apparatus of claim 1 , wherein after being propelled and coming to a stop, the dual-wheel motorized caster is controlled by the power drive circuitry to swivel into a rest orientation having the drive direction oriented parallel with a longitudinal dimension of the patient support apparatus. 13 . The patient support apparatus of claim 1 , further comprising at least one collision avoidance sensor coupled to the frame and operable to provide an obstacle detect sensor signal to the power drive circuitry, wherein the power drive circuitry uses the obstacle detect sensor signal to cease propulsion of the patient support apparatus or to swivel the dual-wheel motorized caster so as to steer the patient support apparatus in a manner that avoids or minimizes a collision with a detected obstacle. 14 . The patient support apparatus of claim 13 , wherein the at least one collision avoidance sensor comprises a first collision avoidance sensor associated with a front of the frame, a second collision avoidance sensor associated with a rear of the frame, a third collision avoidance sensor associated with a right side of the frame, and a fourth collision avoidance sensor associated with a left side of the frame. 15 . The patient support apparatus of claim 13 , wherein the at least one collision avoidance sensor comprises a first pair of collision avoidance sensors associated with a front of the frame, a second pair of collision avoidance sensors associated with a rear of the frame, a third pair of collision avoidance sensors associated with a right side of the frame, and a fourth pair of collision avoidance sensors associated with a left side of the frame. 16 . The patient support apparatus of claim 13 , wherein the at least one collision avoidance sensor comprises at least one of the following sensor technologies: RADAR, LiDAR, video, forward looking infrared RADAR (FLIR), and ultrasound. 17 . The patient support apparatus of claim 13 , wherein the at least one collision avoidance sensor comprises a first collision avoidance sensor that operates according to a first technology of the following sensor technologies: RADAR, LiDAR, video, forward looking infrared RADAR (FLIR), and ultrasound, and wherein the at least one collision avoidance sensor comprises a second collision avoidance sensor that operates according to a second technology of the following sensor technologies: RADAR, LiDAR, video, forward looking infrared RADAR (FLIR), and ultrasound, the second technology being different than the first technology. 18 . The patient support apparatus of claim 1 , wherein the power drive circuitry is configured for communication with one or more other patient support apparatuses to implement cooperative behavior between the patient support apparatuses for purpos