Medical imaging examination apparatus having multiple sub-systems and method for the operation thereof

The invention claimed is: 1. A method for operating medical imaging scanner comprising a plurality of scanner hardware sub-systems, said method comprising: using a controller of the scanner in order to operate the hardware sub-systems in coordination with each other, by providing the respective hardware sub-systems with respective setting parameters from the controller that define respective functions performed by the respective hardware sub-systems, in order to execute a plurality of successive repetitions of a measurement sequence so as to acquire image data from an imaging volume of a subject situated in the scanner, with image data in each repetition of the measurement sequence being acquired only from a respective sub-volume of said imaging volume, with said sub-volumes being different from repetition-to-repetition of the measurement sequence; in a computer, selecting first setting parameters, among said setting parameters, that are to be constant during each repetition of said measurement sequence, and implementing a static adjustment of said first setting parameters in which each first setting parameter is set to a constant value that will not change during a respective repetition of the measurement sequence; in said computer, selecting second setting parameters, among said setting parameters, that can vary during each repetition of said measurement sequence and that will be dynamically adjusted during each repetition of said measurement sequence; with said computer, before starting a first repetition of said measurement sequence, operating the scanner so as to measure base data that are to be used by said controller to dynamically adjust said second setting parameters, said base data being dependent on the constant values of the first setting parameters, and storing said base data in a memory for a duration of said first repetition of said measurement sequence, associated with reference values that designate the constant values of the first setting parameters that existed when the base data were measured; from said computer, providing control signals to said controller in order to operate said scanner with said controller so as to execute said first repetition of said measurement sequence with said first setting parameters at said constant values and with dynamic adjustment of said second setting parameters by said controller according to said base data stored in said memory; before each subsequent repetition of said measurement sequence, repeating said static adjustment of said first setting parameters in said computer so as to set said first setting parameters to updated constant values, and thereby changing at least one of said reference values in said memory; in said computer, also updating said base data in said memory, before each subsequent repetition of said measurement sequence, dependent on said at least one changed reference value, thereby producing updated base data, and retaining said updated base data in said memory during the respective subsequent repetition of said measurement sequence for which the updated base data were produced; from said computer, providing further control signals to said controller in order to operate said scanner with said controller so as to execute each subsequent repetition of said measurement sequence, with said updated first setting parameters and with dynamic adjustment of said second setting parameters according to the updated base data in the memory, until image data have been acquired from all of said sub-volumes; and in said computer, making the image data acquired from said sub-volumes available in electronic form as a datafile comprising image data for an entirety of said image volume. 2. A method as claimed in claim 1 wherein measuring said base data comprises: operating said scanner in order to obtain respective sets of base data individually for each of a plurality of different measurement sequences, or a plurality of different effective volumes, or a plurality of different total volumes. 3. A method as claimed in claim 1 comprising: selecting said first setting parameters from the group consisting of center frequency, first-order shim parameters, and higher-order shim parameters; selecting said second setting parameters from the group consisting of a transmitter scaling parameter and B1 shim parameters. 4. A method as claimed in claim 3 wherein said base data represent values of at least one of a basic magnetic (B0) field in said scanner, and a local radio frequency field in said scanner. 5. A method as claimed in claim 4 wherein said change occurs in the static setting of at least one of said center frequency and one of said shim parameters, and calculating a B0 field map as said base data, updated by addition of a difference field defined by a difference in said center frequency and by addition of difference fields defined by the changed shim parameters together with field changes per unit of current for each shim coil. 6. A method as claimed in claim 4 comprising, when said at least one reference value in said memory that is changed by updating said first setting parameters, omitting any updating to said B0 field represented in said base data in said memory. 7. A method as claimed in claim 3 wherein said change is a change of said transmitter scaling parameter that specifies a reference voltage required for RF transmit coils of the data acquisition scanner in order to generate a predetermined B1 reference field of strength, and calculating a B1 field map as said base data updated by scaling a ratio of a current reference voltage to a reference voltage in said reference values. 8. A medical imaging apparatus comprising: a medical imaging scanner comprising a plurality of scanner hardware sub-systems; a controller of the scanner configured to operate the hardware sub-systems in coordination with each other, by providing the respective hardware sub-systems with respective setting parameters from the controller that define respective functions performed by the respective hardware sub-systems, in order to execute a plurality of successive repetitions of a measurement sequence so as to acquire image data from an imaging volume of a subject situated in the scanner, with image data in each repetition of the measurement sequence being acquired only from a respective sub-volume of said imaging volume, with said sub-volumes being different from repetition-to-repetition of the measurement sequence; a computer configured to select first setting parameters, among said setting parameters, that are to be constant during each repetition of said measurement sequence, and to implement a static adjustment of said first setting parameters in which each first setting parameter is set to a constant value that will not change during a respective repetition of the measurement sequence; said computer being configured to select second setting parameters, among said setting parameters, that can vary during each repetition of said measurement sequence and that will be dynamically adjusted during each repetition of said measurement sequence; said computer being configured to operate the scanner, before starting a first repetition of said measurement sequence, so as to measure base data that are to be used by said controller to dynamically adjust said setting parameters, said base data being dependent on the constant values of the first setting parameters, and to store said base data in a memory for a duration of said first repetition of said measurement sequence, associated with reference values that designate the constant values of the first setting parameters that existed when the base data were measured; said computer being configured to provide control signals to said controller in order to operate said scann