Magnetic resonance imaging method and apparatus

We claim as our invention: 1. A method for automated magnetic resonance (MR) imaging of a patient, comprising: providing a processor with an MR overview image that represents a patient who is to be subsequently examined in a scan using an MR data acquisition unit having an imaging volume; in said processor, designating, within said MR overview image, a plurality of respectively different scanning ranges respectively for acquiring MR partial images from the patient in the subsequent scan, that each comprise respectively different anatomic regions of the patient, each of said scanning ranges having a length along a selected direction that is dependent on the anatomic region thereof and at least two of said lengths being different from each other; in said processor, identifying a longest scanning range, among said plurality of scanning ranges, that has a longest length along said selected direction, and defining said longest length of said longest scanning range as a maximum length; in said processor, executing a check to determine whether the longest length of the longest scanning range exceeds a length of said imaging volume of said data acquisition unit in said selected direction; in said processor, the length along said selected direction of each of said scanning regions to be equal to said maximum length only if said check determines that said maximum length does not exceed the length of said imaging volume in said selection direction; positioning the patient in said MR data acquisition unit along said selected direction and operating said MR data acquisition unit to acquire the respective MR partial images, that respectively represent the anatomic regions within the respective scanning ranges extended to said maximum length; and in said processor, composing an overall MR image of the patient by combining said MR partial images, and making said overall MR image available at an output of the processor in electronic form, as a data file. 2. A method as claimed in claim 1 comprising, in said processor, when determining said scanning ranges, setting the respective links thereof to maintain a position of a central point in each of the respective scanning ranges to be basically constant along said selected direction. 3. A method as claimed in claim 1 wherein said selected direction is a first direction, and comprising; in said processor, determining said plurality of scanning ranges to have, in addition to said length in said first direction, a length in a second direction and a length in a third direction, said first direction, said second direction and said third direction being orthogonal to each other; in said processor, identifying a scanning range, among said plurality of scanning ranges that has a longest length along said second direction and defining said longest length along said second direction as a maximum second length; in said processor, identifying a scanning range, among said plurality of scanning ranges that has a longest length along said third direction and defining said longest length along said third direction as a maximum third length; in said processor, for each of said scanning ranges, setting the length along the second direction to be equal to said second maximum length; and in said processor, for each of said scanning ranges, setting the length along the third direction to be equal to said third maximum length. 4. A method as claimed in claim 3 comprising: in said processor, setting said length along said second direction to cause a position of a central point of the scanning ranges along said second direction to be equal to a position of the central point of the scanning range having said longest length along said second direction; and in said processor, setting said length along said third direction to cause a position of a central point of the scanning ranges along said third direction to be equal to a position of the central point of the scanning range having said longest length along said third direction. 5. A method as claimed in claim 3 comprising, during operation of said MR data acquisition unit to generate said MR partial images, activating spatially encoding magnetic gradient fields, and respectively adjusting said magnetic gradients fields along at least one of said first direction, said second direction and said third direction. 6. A method as claimed in claim 1 comprising: in said processor, for each of said scanning ranges, comparing an extent of any overlap that exists along said selected direction between adjacent scanning ranges, to a threshold value, to obtain an overlap comparison result; and in said processor, selectively extending the length along said selected direction for all of said scanning ranges dependent on said overlap comparison result. 7. A method as claimed in claim 1 comprising operating said MR data acquisition unit with the same MR data acquisition sequence to acquire all of said MR partial images. 8. A method as claimed in claim 7 comprising, in said processor, setting parameters for said MR measuring sequence selected from the group consisting of number of pixels in each of said MR partial images, concentration of pixels in each of said MR partial images, an echo time during which magnetic resonance signals for said MR partial images are acquired, and a repetition time between radiated radio-frequency excitation pulses that excite nuclear spins in the patient to generate MR signals for each of said MR partial images. 9. A method as claimed in claim 8 comprising setting said parameters dependent on the maximum length along said selected direction of said scanning ranges. 10. A method as claimed in claim 1 comprising: in said processor, comparing said maximum length, to which the length along the selected direction of each of said scanning ranges has been set, to a predetermined length threshold value; and when said maximum length exceeds said length threshold value, automatically dividing, in said processor, each of said scanning ranges into two scanning ranges. 11. A magnetic resonance (MR) apparatus comprising: an MR data acquisition unit having an imaging volume; a processor provided with an MR overview image that represents a patient who is to be subsequently examined in a scan using an MR data acquisition unit; said processor being configured to designate, within said MR overview image, a plurality of respectively different scanning ranges respectively for acquiring MR partial images from the patient in the subsequent scan, that each comprise respectively different anatomic regions of the patient, each of said scanning ranges having a length along a selected direction that is dependent on the anatomic region thereof and at least two of said lengths being different from each other; said processor being configured to identify a longest scanning range, among said plurality of scanning ranges, that has a longest length along said selected direction, and defining said longest length of said longest scanning range as a maximum length; said processor being configured to execute a check to determine whether the longest length of the longest scanning range exceeds a length of said imaging volume of said data acquisition unit in said selected direction; said processor being configured to extend the length along said selected direction of each of said scanning regions to be equal to said maximum length only if said check determines that said maximum length does not exceed the length of said imaging volume in said selection direction; a control unit configured to operate the MR data acquisition unit with the patient positioned in the MR data acquisition unit along said selected direction, to acquire the respective