System and method for controlling material drop volume in three dimensional object printing

What is claimed: 1. A printer comprising: a planar support member; a printhead positioned to eject drops of material towards the support member, at least one of the planar support member and the printhead being configured to move relative to the other of the planar support member and the printhead; a specular sensor array having an illumination source and a plurality of light receivers, the illumination source being configured to emit light at a predetermined angle to the planar support member and each light receiver being configured to generate an electrical signal corresponding to light reflected from ejected material on the planar support member; and a controller operatively connected to the planar support member, the printhead, and the specular sensor array, the controller being configured to: operate the printhead to form at least two objects on the planar support member; operate one of the planar support member and the printhead to move relative to the other of the planar support member and the printhead to enable the at least two objects to have a length in a cross-process direction that substantially covers a width of the printhead across the planar support member and have a length in a process direction that extends along a portion of the planar support member in a process direction; operate the specular sensor array to direct light towards the planar support member and receive the electrical signals generated by the light receivers as one of the specular sensor array and the planar support member move relative to the other of the specular sensor array and the planar support member; analyze image data corresponding to the electrical signals received from the light receivers to identify a ratio between a difference in shadow distances identified by a response of the light receivers to reflected light at an edge of the two objects and a difference in height between the two objects; and adjust an operational parameter of the printhead in response to the analyzed image data indicating a mass of material drops ejected by an inkjet in the printhead has change with reference to a predetermined material drop mass. 2. The printer of claim 1 wherein the illumination source and the plurality of light receivers in the specular sensor array extend in the cross-process direction along a distance corresponding to the width of the printhead in the cross-process direction. 3. The printer of claim 1 , the illumination source is further configured to emit at least two colors of light; and the controller being further configured to select one of two colors of light to be emitted by the illumination source. 4. The printer of claim 1 , the plurality of light receivers being configured to generate the electrical clock signals for a plurality of integration periods; and the controller being further configured to select one of the integration periods during which the light receivers generate the electrical signals. 5. The printer of claim 1 , the controller being further configured to: operate the printhead to form at least a portion of one object at a first predetermined height and to form the second object at a second predetermined height, the first predetermined height being greater than the second predetermined height. 6. The printer of claim 5 , the controller being further configured to: operate the printhead to form the at least portion of the one object at the first predetermined height that is ten times greater than the second predetermined height. 7. The printer of claim 5 , the controller being further configured to: operate the printhead to form the portion of the one object at the first predetermined height and to form another portion of the one object at a third predetermined height, the third predetermined height being less than the first predetermined height and greater than the second predetermined height. 8. The printer of claim 1 , wherein a number of light receivers are greater than a number of drops per inch that the printhead can eject in a line extending in the cross-process direction. 9. The printer of claim 1 , the controller being further configured to move the specular sensor array in the cross-process direction to enable an increased resolution of the image data in the cross-process direction. 10. The printer of claim 1 , the controller being further configured to move the specular sensor array in the process direction to enable an increased resolution of the image data in the process direction. 11. The printer of claim 1 wherein the specular sensor array is rotated with reference to the process direction to enable a sampling resolution of the specular sensor array to be increased in the cross-process direction. 12. The printer of claim 1 , the controller being further configured to identify a thickness difference between two areas of the ejected material, the thickness difference being identified with reference to an absorption coefficient of the ejected material, the electrical signals corresponding to the light sensed by the specular sensor array, and a location of the specular sensor array with respect to the illumination source.