Medical imaging apparatus having multiple subsystems, and operating method therefor

We claim as our invention: 1. A method for operating a medical imaging examination apparatus comprising a plurality of apparatus subsystems, comprising: providing a control protocol to control computer that is assigned to a scan sequence in which said control computer will control the plurality of apparatus subsystems in coordination to conduct the scan sequence to acquire medical imaging data from an examination subject; in said control computer, determining sequence control data for said control protocol that define different functional sub-sequences of said scan sequence to be performed respectively by said apparatus subsystems; in said control computer, assigning respectively different effective volumes of the examination subject to the respective functional sub-sequences; in said control computer, determining current ambient conditions of said medical imaging examination apparatus that affect said sequence control data and said effective volumes; in said control computer, calculating and storing control signals for said scan sequence dependent on said determined sequence control data, the determined effective volumes, and the determined current ambient conditions, by executing an algorithm in said control computer that optimizes the functional sub-sequences locally in the examination subject at least with regard to a sub-region of the respective effective volumes; and in said control computer, starting said scan sequence using the stored control signals and, during said scan sequence, providing said control computer with a designation of at least one change of a sub-region of a respective effective volume, and automatically adapting said control signals for a remainder of said scan sequence dependent on said change, to maintain the optimization of the functional sub-sequences locally at least with regard to the changed sub-region. 2. A method as claimed in claim 1 comprising calculating and storing said control signals dependent on, for each sub-region to be optimized, a predetermined tolerance range that designates an amount by which the respective sub-region can be displaced, and adapting said control signals only when said change is larger than said tolerance region. 3. A method as claimed in claim 1 comprising adapting said control signals using control signals, among said stored control signals, that were calculated for a sub-region to be optimized that corresponds as closely as possible to the changed sub-region. 4. A method as claimed in claim 1 comprising calculating and storing said control signals for each functional subsequence for multiple, different effective volumes that are varies in a predetermined variation, at least with respect to sub-regions thereof, thereby producing stored control signals for respective, different variations of said sub-regions to be optimized in the respective effect volumes. 5. A method as claimed in claim 1 comprising adapting said control signals by interpolating control signals among said stored control signals. 6. A method as claimed in claim 1 comprising determining said at least one change of a sub-region of a respective effective volume continuously during said scan sequence, dependent on at least one of location and position changes of the examination subject. 7. A method as claimed in claim 1 comprising determining said at least one change of a sub-region of a respective effective volume during said scan sequence using at least one of information relating to said scan sequence, movement information detected by an external movement sensor, and movement information detected within said scan sequence. 8. A method as claimed in claim 1 comprising calculating said control signals together with a plausibility check. 9. A medical imaging examination apparatus comprising: a plurality of apparatus subsystems; a control computer provided with a control protocol that is assigned to a scan sequence in which said control computer is configured to control the plurality of apparatus subsystems in coordination to conduct the scan sequence to acquire medical imaging data from an examination subject; said control computer being configured to determine sequence control data for said control protocol that define different functional sub-sequences of said scan sequence to be performed respectively by said apparatus subsystems; said control computer being configured to assign respectively different effective volumes of the examination subject to the respective functional sub-sequences; said control computer being configured to determine current ambient conditions of said medical imaging examination apparatus that affect said sequence control data and said effective volumes; said control computer being configured to calculate and store control signals for said scan sequence dependent on said determined sequence control data, the determined effective volumes, and the determined current ambient conditions, by executing an algorithm in said control computer that optimizes the functional sub-sequences locally in the examination subject at least with regard to a sub-region of the respective effective volumes; and said control computer being configured to start said scan sequence using the stored control signals and, during said scan sequence, receive a designation of at least one change of a sub-region of respective effective volume, and automatically adapt said control signals for a remainder of said scan sequence dependent on said change, to maintain the optimization of the functional sub-sequences locally at least with regard to the changed sub-region. 10. A medical imaging examination apparatus as claimed in claim 9 wherein said plurality of apparatus subsystems form a magnetic resonance scanner. 11. A non-transitory, computer-readable data storage medium encoded with programming instructions, said storage medium being loaded into a control computer of a medical imaging examination apparatus comprising a plurality of apparatus subsystems, said programming instructions causing said control computer to: receive a control protocol that is assigned to a scan sequence in which said control computer will control the plurality of apparatus subsystems in coordination to conduct the scan sequence to acquire medical imaging data from an examination subject; determine sequence control data for said control protocol that define different functional sub-sequences of said scan sequence to be performed respectively by said apparatus subsystems; assign respectively different effective volumes of the examination subject to the respective functional sub-sequences; determine current ambient conditions of said medical imaging examination apparatus that affect said sequence control data and said effective volumes; calculate and store control signals for said scan sequence dependent on said determined sequence control data, the determined effective volumes, and the determined ambient conditions, by executing an algorithm that optimizes the functional sub-sequences locally in the examination subject at least with regard to a sub-region of the respective effective volumes; and start said scan sequence using the stored control signals and, during said scan sequence, receive a designation of at least one change of a sub-region of a respective effective volume, and automatically adapt said control signals for a remainder of said scan sequence, dependent on said change, to maintain the optimization of the functional sub-sequences locally at least with regard to the changed sub-region.