LIM-driven roller checkweigher

What is claimed is: 1. A weighing conveyor system comprising: an upstream conveyor having a downstream end and conveying objects in a conveying direction to the downstream end; a downstream conveyor having an upstream end and receiving the objects conveyed by the upstream conveyor; a roller transfer device interposed between the downstream end of the upstream conveyor and the upstream end of the downstream conveyor and transferring the objects received from the upstream conveyor to the downstream conveyor in the conveying direction, the roller transfer device including: a roller drive system; an array of rollers, at least some of which are active rollers rotated by the roller drive system at a constant torque to propel the objects received from the upstream conveyor in the conveying direction to the downstream conveyor, wherein the acceleration of each of the objects in the conveying direction on the roller transfer device is inversely proportional to the object's weight; a sensor system determining the change in the gap between consecutive objects or in the spacing of consecutive objects before and after they are propelled in the conveying direction by the active rollers to determine the weight of each of the objects. 2. A weighing conveyor system as in claim 1 wherein the roller drive system comprises a linear-induction-motor stator producing a magnetic flux wave passing through the active rollers and wherein the active rollers include electrically conductive material interacting inductively with the magnetic flux wave to rotate the active rollers at constant torque to propel the objects on the roller transfer device in the conveying direction. 3. A weighing conveyor system as in claim 1 wherein the sensor system detects each of the objects at one or more positions along the conveying direction. 4. A weighing conveyor system as in claim 1 wherein the sensor system comprises a first pair of sensors near the downstream end of the upstream conveyor to measure the gap between or spacing of consecutive objects entering the roller transfer device and a second pair of sensors near the upstream end of the downstream conveyor to measure the gap between or spacing of consecutive objects exiting the roller transfer device. 5. A weighing conveyor system as in claim 1 wherein the sensor system comprises a pair of sensors at spaced apart locations in the conveying direction along the roller transfer device. 6. A weighing conveyor system as in claim 1 wherein a first group of the active rollers in the roller transfer device form a first roller zone adjacent the downstream end of the upstream conveyor and a second roller zone downstream of the first roller zone in the conveying direction and wherein the array of rollers includes passive rollers forming a middle roller zone between the first and second roller zones, wherein the objects entering the roller transfer device at a first speed are decelerated in the first roller zone to a coast speed, allowed to coast at the coast speed in the middle roller zone to the second roller zone, and accelerated in the second roller zone to exit the roller transfer device at a second speed. 7. A weighing conveyor system as in claim 6 wherein the second speed equals the first speed. 8. A weighing conveyor system as in claim 6 wherein the sensor system determines the coast speed. 9. A checkweigher comprising: a roller transfer device including: a roller drive system; an array of rollers, at least some of which are active rollers rotated by the roller drive system at a constant torque to propel objects in a conveying direction, wherein the acceleration of each of the objects in the conveying direction on the roller transfer device is inversely proportional to the object's weight; a sensor system determining the change in the gap between consecutive objects or in the spacing of consecutive objects before and after they are propelled in the conveying direction by the active rollers to determine the weight of each of the objects. 10. A checkweigher as in claim 9 wherein the roller drive system comprises a linear-induction-motor stator producing a magnetic flux wave passing through the active rollers and wherein the active rollers include electrically conductive material interacting inductively with the magnetic flux wave to rotate the active rollers at constant torque to propel the objects on the roller transfer device in the conveying direction. 11. A checkweigher as in claim 9 wherein the sensor system comprises a controller and two or more position sensors providing output signals to the controller indicating the positions of objects upstream and downstream of the active rollers from which the controller computes the weights of objects. 12. A method for weighing conveyed objects, comprising: conveying objects separated by a gap in a conveying direction to an array of rollers; rotating the array of rollers with a constant torque to accelerate each of the objects in the conveying direction to a speed that is inversely proportional to the weight of the object; determining the weight of each of the objects from the change in the gap caused by the array of rollers. 13. The method of claim 12 wherein the objects are conveyed to the array of rollers with the same gap between consecutive objects.