Variable placement hinge for agricultural implement to maintain constant work zone spacing

We claim: 1. A method of maintaining a constant spacing between adjacent work zones of an agricultural implement, the method including: interconnecting first and second adjacent implement sections of the agricultural implement; determining a target spacing between the adjacent implement sections of an agricultural implement which define the adjacent work zones, the target spacing between the adjacent implement sections corresponding to a row spacing of adjacent rows of seeds and defining boundaries between the adjacent work zones; detecting a deviation from the target spacing with a sensor arrangement; and moving at least one of the implement sections to attenuate the deviation from the target spacing. 2. The method of claim 1 wherein the agricultural implement includes a hinge joint defining a hinge pivot axis allowing the adjacent implement sections to pivot with respect to each other and a pivot knuckle supporting the hinge joint and defining a knuckle pivot axis about which the pivot knuckle pivots for moving the hinge joint toward or away from a centerline of the agricultural implement to adjust spacing between the adjacent implement sections and attenuate the deviation from the target spacing. 3. The method of claim 2 , further comprising a second sensor arrangement for detecting a working mode or a nonworking mode of the agricultural implement, wherein when the working mode is detected, a controller commands movement of a pivot knuckle to adjust spacing between the work zones and attenuate the deviation from the target spacing and, when the nonworking mode is detected, the controller commands movement of pivot knuckle to a neutral position. 4. The method of claim 1 wherein detecting the deviation from the target spacing includes detecting at least one of a change in a vertical position and change in a relative angle between respective implement sections. 5. The method of claim 4 wherein the first implement section defining a reference implement section, and the change in relative angle is detected between the second implement section and the reference implement section. 6. The method of claim 5 further comprising the step of defining an angle of deviation such that when a positive angle of deviation is detected corresponding to the second implement section extending angularly upwardly relative to the reference implement section, the second implement section is moved closer to the reference implement section and when a negative angle of deviation is detected corresponding to the second implement section extending angularly downwardly relative to the reference implement section, the second implement section is moved away from the reference implement section. 7. The method of claim 6 wherein an amount of movement of the second implement section closer to the reference implement section corresponds to an amount of upward angular deviation of the second implement section relative to the reference implement section. 8. The method of claim 7 wherein the sensor arrangement includes an angle sensor is arranged with respect to the reference and second implement sections to provide a signal corresponding to the detected positive angle of deviation to a controller that controls an actuator to move the second implement section closer to the reference implement section. 9. The method of claim 8 wherein the signal from the angle sensor corresponds to a change in position of the second implement relative to a base-calibrated zero position in which the reference and second implement sections are aligned with or parallel to each other. 10. The method of claim 9 wherein the sensor arrangement includes an axis position sensor and wherein an angular value corresponding to the change in position of the angle of deviation is compared to an axis position of the hinge pivot axis determined at least in part by the axis position sensor. 11. The method of claim 10 wherein the controller is activated to command movement of the hinge pivot axis based on a signal from the axis position sensor and the angle of deviation. 12. The method of claim 6 wherein an amount of movement of the second implement section away from the reference implement section corresponds to an amount of downward angular deviation of the second implement section relative to the reference implement section. 13. The method of claim 12 wherein the sensor arrangement includes an angle sensor, the angle sensor being arranged with respect to the reference and second implement sections to provide a signal corresponding to the detected negative angle of deviation to a controller that controls an actuator to move the second implement section away from the reference implement section. 14. The method of claim 13 wherein the signal from the angle sensor corresponds to a change in position of the second implement relative to a base-calibrated zero position in which the reference and second implement sections are aligned with or parallel to each other. 15. The method of claim 14 wherein the sensor arrangement includes an axis position sensor and wherein an angular value corresponding to the change in position of the angle of deviation is compared to an axis position of the hinge pivot axis determined at least in part by the axis position sensor. 16. The method of claim 15 wherein the controller is activated to command movement of the hinge pivot axis based on a signal from the axis position sensor and the angle of deviation. 17. A method of maintaining a constant spacing between adjacent work zones of an agricultural implement, the method including: interconnecting first and second adjacent implement sections of the agricultural implement, the first implement section extending along an axis; determining a target spacing along the axis between the adjacent implement sections, wherein a hinge joint is arranged between the adjacent implement sections to allow pivoting therebetween about a hinge pivot axis and movement of the second implement along the axis; and moving the hinge pivot axis to maintain the target spacing between the adjacent implement sections; wherein the first and second adjacent implement sections define the work zones of the agricultural implement. 18. The method of claim 17 further comprising pivoting the hinge joint about a knuckle pivot axis to move from the hinge pivot axis for maintaining the target spacing between the adjacent implement sections and wherein the knuckle pivot axis is defined at a pivot knuckle arranged between the hinge joint and at least one of the adjacent implement sections. 19. An agricultural implement, comprising: a first implement section extending along an axis and defining a first work zone covering a first portion of an agricultural field worked by the first implement section; a second implement section spaced from first implement section along the axis and defining a second work zone covering a second portion of an agricultural field worked by the second implement section; a hinge joint arranged between the first and second sections allowing flexing of the agricultural implement for accommodating uneven surfaces of the agricultural field; and a pivot knuckle arranged between the hinge joint and at least one of the first and second implement sections, the pivot knuckle movable for moving the hinge joint to maintain a constant spacing along the axis between the work zones. 20. The agricultural implement of claim 19 further comprising an angle sensor arranged with respect to the first and second implement sections to