Motion sensor

We claim as our invention: 1 . A motion sensor for detecting movements of a subject in a medical imaging system, said motion sensor comprising: at least one radio-frequency (RF) resonator; an RF signal source in signal-feeding communication with said at least one RF resonator, said RF signal source generating an RF signal that is fed to said RF resonator and that causes said RF resonator to radiate an RF field in which said subject is situated; and a detection circuit in signal-receiving communication with said RF resonator that detects signals produced by said RF resonator as a result of subject movement in said RF field, said detection circuit generating a detection circuit output signal that represents said movement. 2 . A motion sensor as claimed in claim 1 wherein said medical imaging system is a magnetic resonance system in which RF excitation pulses, for obtaining magnetic resonance image data, are radiated at an excitation frequency, and wherein said signal source generates said RF signal that is fed to said RF resonator at a frequency that differs from said excitation frequency. 3 . A motion sensor as claimed in claim 1 comprising a plurality of RF resonators. 4 . A motion sensor as claimed in claim 1 wherein said RF resonator comprises an LC resonator comprising at least one coil and at least one capacitor. 5 . A motion sensor as claimed in claim 1 wherein said detection circuit is a narrow band RF detection circuit. 6 . A method as claimed in claim 1 wherein said detection circuit is configured to measure differences in the detected signal from the RF resonator that represent inhalation by the patient and exhalation by the subject, respectively. 7 . A motion sensor as claimed in claim 1 wherein the subject is a patient, and wherein said RF resonator is configured for placement at a location relative to the patient selected from the group consisting of above a chest region of the patient, below a chest region of the patient, above an abdominal region of a patient and below an abdominal region of the patient. 8 . A motion sensor as claimed in claim 1 wherein said medical imaging system comprises an examination table adapted to receive the subject thereon, and wherein at least said RF resonator is integrated in said examination table. 9 . A motion sensor as claimed in claim 1 wherein said medical imaging system is a magnetic resonance imaging system comprising a scanner having a housing shell forming a patient receptacle adapted to receive the subject therein, and wherein said RF resonator is configured for placement above the patient in the receptacle, with the RF resonator being behind said housing shell. 10 . A motion sensor as claimed in claim 1 wherein said RF resonator has resonator characteristic selected from the group consisting of a loaded quality and a transmission factor, and wherein said detection circuit is configured to detect said movement as a change in said resonator characteristic. 11 . A motion sensor as claimed in claim 1 wherein said detection circuit is configured to detect said movement by evaluating a temporal change in transmission of said RF signal to said RF radiator. 12 . A motion sensor as claimed in claim 1 wherein said RF signal has a wavelength, and wherein said RF resonator has physical dimensions that are smaller than said wavelength of said RF signal. 13 . A motion sensor as claimed in claim 1 wherein said Rf resonator is configured as an inductive sensor operating in an inductive near field. 14 . A motion sensor as claimed in claim 1 wherein said Rf resonator is configured as a capacitive sensor operating in a capacitive near field. 15 . A motion sensor as claimed in claim 1 wherein said RF resonator is configured for placement relative to the subject without making contact with the subject. 16 . A motion sensor as claimed in claim 1 wherein said RF source is configured to generate said RF signal with a power of less than 10 mW. 17 . A motion sensor as claimed in claim 1 wherein said RF signal source and said detector circuit are capacitively coupled to said RF resonator. 18 . A motion sensor as claimed in claim 1 wherein said RF signal source and said detector circuit are capacitively decoupled from said RF resonator. 19 . A motion sensor as claimed in claim 1 wherein said RF signal source and said detector circuit are inductively coupled to said RF resonator. 20 . A motion sensor as claimed in claim 1 wherein said RF signal source and said detector circuit are inductively decoupled from said RF resonator. 21 . A medical imaging system comprising: a motion sensor comprising at least one radio-frequency (RF) resonator, an RF signal source in signal-feeding communication with said at least one RF resonator, said RF signal source generating an RF signal that is fed to said RF resonator and that causes said RF resonator to radiate an RF field in which said subject is situated, and a detection circuit in signal-receiving communication with said RF resonator that detects signals produced by said RF resonator as a result of subject movement in said RF field, said detection circuit generating a detection circuit output signal that represents said movement; a medical data acquisition scanner adapted to receive the subject therein; a control computer configured to operate said medical data acquisition scanner to acquire medical data from the subject; and said control computer being connected to said detector circuit and being configured to adapt the acquisition of said medical image data from the subject dependent on the motion represented in said detector circuit output. 22 . A method for detecting motion of a subject in a medical imaging system, said method comprising placing at least one radio-frequency (RF) resonator; placing an RF signal source in signal-feeding communication with said at least one RF resonator and, in said RF signal source, generating an RF signal and feeding said RF signal to said RF resonator and to cause said RF resonator to radiate an RF field in which said subject is situated; and placing a detection circuit in signal-receiving communication with said RF resonator and detecting signals produced by said RF resonator as a result of patient movement in said RF field and, from said detection circuit generating a detection circuit output signal that represents said movement.