Method for operating a magnetic-inductive flowmeter and corresponding magnetic-inductive flowmeter

The invention claimed is: 1. A method for operating a magnetic-inductive flowmeter with a measuring tube for guiding a medium, with a magnetic field generator for generating a magnetic field passing through the measuring tube perpendicular to the direction of flow of the medium, and with a pair of electrodes for tapping an electrical voltage induced in the medium in the measuring tube as a noisy raw measurement signal, the method comprising: detecting the noisy raw measurement signal having a first signal path by a signal sensor with high impedance by the pair of electrodes; passing the detected, noisy raw measurement signal on to a first signal processing device; processing the detected, noisy raw measurement signal by the signal processing device at least into a noise-removed flow measurement signal; outputting the noise-removed flow measurement signal via a working signal interface; detecting the detected, noisy raw measurement signal of the first signal path with a second signal path; periodically reversing the magnetic field generated by the magnetic field generator; and transmitting the detected, noisy raw measurement signal at least indirectly to the first signal processing device and/or a second signal processing device; wherein the first signal processing device and/or the second signal processing device carries out a plurality of frequency analyses of only portions of the detected, noisy raw measurement signal that originate from respective time windows in which the magnetic field is constant; and wherein respective frequency-dependent result values of the plurality of frequency analyses are averaged to form an averaged frequency analysis. 2. The method according to claim 1 , wherein the signal sensor of the first signal path digitizes the noisy raw measurement signal with an analog/digital converter and passes the noisy raw measurement signal on as a digitized, detected, noisy raw measurement signal; and wherein the second signal path detects the digitized, detected, noisy raw measurement signal of the first signal path and transmits the digitized, detected, noisy raw measurement signal to the first signal processing device and/or the second signal processing device. 3. The method according to claim 1 , wherein the signal sensor of the first signal path taps the noisy raw measurement signal from the electrodes with a high impedance with a transformer stage and passes the noisy raw measurement signal tapped with a high impedance on with a low impedance; wherein the second signal path detects the detected, noisy raw measurement signal of the first signal path which is passed on with low impedance and transmits the detected, noisy raw measurement signal to the first signal processing device and/or the second signal processing device; and wherein the detected, noisy raw measurement signal transmitted to the first signal processing device and/or the second signal processing device is digitized in the second signal path by the analog/digital converter and the digitized, detected, noisy raw measurement signal is transmitted to the first signal processing device and/or the second signal processing device. 4. The method according to claim 1 , wherein the noisy raw measurement signal detected by the second measurement signal path is transmitted at least indirectly via a further signal interface of the magnetic-inductive flowmeter, which is different from the working signal interface, to the second signal processing device external to the magnetic-inductive flowmeter. 5. The method according to claim 1 , wherein the noisy raw measurement signal detected by the second measurement signal path is transmitted to the first signal processing device and/or the second signal processing device within the magnetic-inductive flowmeter. 6. The method according to claim 1 , wherein each of the plurality of frequency analyses involves performing a fast Fourier transform; and wherein a number of the noisy raw measurement signals is increased to the next higher power of two by zero padding if the number of noisy raw measurement values of a time window available for the plurality of frequency analyses does not correspond to a power of two. 7. A magnetic-inductive flowmeter, comprising: a measuring tube for guiding a medium; a magnetic field generator for generating a magnetic field passing through the measuring tube perpendicular to the direction of flow of the medium; a pair of electrodes for tapping an electrical voltage induced in the medium in the measuring tube as a noisy raw measurement signal; wherein the noisy raw measurement signal with a first signal path is detected by a signal sensor with high impedance by the pair of electrodes and is passed on as a detected, noisy raw measurement signal from the signal sensor to a first signal processing device and is processed by the first signal processing device at least into a noise-removed flow measurement signal and the noise-removed flow measurement signal is output via a working signal interface; wherein a second signal path is implemented and the detected, noisy raw measurement signal of the first signal path is detected with the second signal path and is transmitted at least indirectly to the first signal processing device and/or a second signal processing device; wherein the first signal processing device and/or the second signal processing device carries out a frequency analysis of the detected, noisy raw measurement signal; and wherein the second signal path and circuit elements in the second signal path are implemented independently of the first signal path and circuit elements of the first signal path in terms of circuitry. 8. The magnetic-inductive flowmeter according to claim 7 , wherein the signal sensor of the first signal path digitizes the noisy raw measurement signal with an analog/digital converter and passes the noisy raw measurement signal on as a digitized, detected, noisy raw measurement signal; and wherein the second signal path detects the digitized, detected noisy raw measurement signal of the first signal path and transmits the digitized, detected noisy raw measurement signal to the first signal processing device and/or the second signal processing device. 9. The magnetic-inductive flowmeter according to claim 7 , wherein the signal sensor of the first signal path taps the noisy raw measurement signal from the electrodes with a high impedance by means of a transformer stage and passes the noisy raw measurement signal tapped with a high impedance on with a low impedance; wherein the second signal path detects the detected, noisy raw measurement signal of the first signal path, which is passed on with low impedance, and transmits the detected, noisy raw measurement signal to the first signal processing device and/or the second signal processing device; and wherein the detected, noisy raw measurement signal transmitted to the first signal processing device and/or the second signal processing device is digitized in the second signal path by an analog/digital converter and the digitized, detected, noisy raw measurement signal is transmitted to the first signal processing device and/or the second signal processing device. 10. The magnetic-inductive flowmeter according to claim 7 , wherein the detected, noisy raw measurement signal is transmitted via a further signal interface of the magnetic-inductive flowmeter, which is different from the working signal interface, to the second signal processing device external to the magnetic- inductive flowmeter. 11. The magnetic-inductive flowmeter according to claim 7 , wherein the detected, noisy raw measurement signal is transmitted to the first signal processing device and/or the s