Module or arrangement for, and method of, reading a target by image capture with an imaging reader having offset imaging and aiming systems

The invention claimed is: 1. An imaging module for reading a target by image capture over a range of working distances away from the module, comprising: an imaging system including an imaging sensor for sensing light returning from the target along an imaging axis over a field of view that extends along mutually orthogonal, horizontal and vertical axes that are generally perpendicular to the imaging axis, the field of view having a width along the horizontal axis and a height along the vertical axis; and an aiming light system offset from the imaging system and including a pair of aiming light assemblies spaced apart along the horizontal axis at opposite sides of the imaging sensor, and operative for directing a pair of aiming light lines, each having a predetermined brightness, along a pair of aiming axes at the target, the aiming light lines being collinear along the horizontal axis and having inner linear end regions that extend past the imaging axis and that overlap on the target to form a bright, linear, aiming mark having a brightness greater than the predetermined brightness to visually indicate a center zone of the field of view over the range of working distances; each aiming light line having a line width that is a first fraction of the width of the field of view, and a line height that is a second fraction of the height of the field of view, the first fraction being greater than the second fraction. 2. The module of claim 1 , wherein the aiming light lines have outer linear end regions that extend along the horizontal axis toward, and that visually indicate, approximate boundary zones of the field of view over the range of working distances. 3. The module of claim 2 , wherein the outer linear end regions have opposite ends that are spaced apart along the horizontal axis by a distance that is slightly less than the width of the field of view over at least part of the range of working distances. 4. The module of claim 1 , wherein each aiming light assembly includes an aiming light emitting diode (LED), an aiming aperture, and an aiming lens. 5. The module of claim 1 , wherein the aiming axes and the imaging axis generally lie in a common plane and are generally parallel to one another. 6. The module of claim 1 , wherein the aiming light lines increase in length, and the field of view increases proportionally in area, in a direction away from the module. 7. An imaging reader for reading a target by image capture over a range of working distances away from the reader, comprising: a housing having a light-transmissive window; and an imaging module mounted in the housing, the module having an imaging system including an imaging sensor for sensing light returning from the target through the window along an imaging axis over a field of view that extends along mutually orthogonal, horizontal and vertical axes that are generally perpendicular to the imaging axis, the field of view having a width along the horizontal axis and a height along the vertical axis, and an aiming light system offset from the imaging system and including a pair of aiming light assemblies spaced apart along the horizontal axis at opposite sides of the imaging sensor, and operative for directing a pair of aiming light lines, each having a predetermined brightness, along a pair of aiming axes through the window at the target, the aiming light lines being collinear along the horizontal axis and having inner linear end regions that extend past the imaging axis and that overlap on the target to form a bright, linear, aiming mark having a brightness greater than the predetermined brightness to visually indicate a center zone of the field of view over the range of working distances; each aiming light line having a line width that is a first fraction of the width of the field of view, and a line height that is a second fraction of the height of the field of view, the first fraction being greater than the second fraction. 8. The reader of claim 7 , wherein the aiming light lines have outer linear end regions that extend along the horizontal axis toward, and that visually indicate, approximate boundary zones of the field of view over the range of working distances. 9. The reader of claim 7 , wherein the outer linear end regions have opposite ends that are spaced apart along the horizontal axis by a distance that is slightly less than the width of the field of view over at least part of the range of working distances. 10. The reader of claim 7 , wherein each aiming light assembly includes an aiming light emitting diode (LED), an aiming aperture, and an aiming lens. 11. The reader of claim 7 , wherein the aiming axes and the imaging axis generally lie in a common plane and are generally parallel to one another. 12. The reader of claim 7 , wherein the aiming light lines increase in length, and the field of view increases proportionally in area, in a direction away from the reader. 13. The reader of claim 7 , wherein the housing has a handle for handheld operation. 14. The reader of claim 7 , wherein the housing has a rear wall spaced away from the window, and wherein the imaging sensor is mounted rearwardly in the housing and closer to the rear wall than to a front of the housing. 15. A method of reading a target by image capture over a range of working distances away from an imaging reader, comprising: sensing light returning from the target through the window along an imaging axis over a field of view that extends along mutually orthogonal, horizontal and vertical axes that are generally perpendicular to the imaging axis, the field of view having a width along the horizontal axis and a height along the vertical axis; directing a pair of aiming light lines, each having a predetermined brightness, along a pair of aiming axes at the target; configuring the aiming light lines to be collinear along the horizontal axis and to have inner linear end regions that extend past the imaging axis and that overlap on the target to form a bright, linear, aiming mark having a brightness greater than the predetermined brightness to visually indicate a center zone of the field of view over the range of working distances; each aiming light line having a line width that is a first fraction of the width of the field of view, and a line height that is a second fraction of the height of the field of view, the first fraction being greater than the second fraction; and positioning the bright aiming mark on the target. 16. The method of claim 15 , and guiding an operator to move the reader to an optimum reading position in the range of working distances by configuring the aiming light lines to have outer linear end regions that extend along the horizontal axis toward, and that visually indicate, approximate boundary zones of the field of view over the range of working distances, and by positioning the outer linear end regions on the target. 17. The method of claim 15 , and configuring the outer linear end regions to have opposite ends that are spaced apart along the horizontal axis by a distance that is slightly less than the width of the field of view over at least part of the range of working distances. 18. The method of claim 15 , and configuring the aiming axes and the imaging axis to generally lie in a common plane and to extend generally parallel to one another. 19. The method of claim 15 , wherein the aiming light lines increase in length, and the field of view increases proportionally in area, in a direction away from the reader. 20. The method of claim 15 , and providing a