Method for operating a Coriolis mass flowmeter and corresponding Coriolis mass flowmeter

The invention claimed is: 1. A method for operating a Coriolis mass flowmeter, wherein the Coriolis mass flowmeter has at least one measuring tube, at least one oscillation generator, at least two oscillation sensors and at least one control and evaluation unit, wherein it is possible for a medium to flow through the measuring tube, wherein the oscillation generator excites the measuring tube into oscillation with an excitation frequency (f 0 ), wherein the first and the second oscillation sensors capture the oscillations of the measuring tube on the inlet side and on the outlet side and provide them as a first oscillation signal with a first oscillation signal phase position (φ S1 ) and as a second oscillation signal with a second oscillation signal phase position (φ S2 ), wherein the control and evaluation unit determines an oscillation signal phase difference (Δφ S ) between the first oscillation signal and the second oscillation signal and determines a mass flow rate from the oscillation signal phase difference (Δφ S ), the method comprising: calculating error-free oscillation signal phase differences (Δφ S,M1 ) using a first measuring channel pair with a first measuring channel phase difference (Δφ M1 ) from the oscillation signals by channel switching, analog/digital conversion, phase detection, digital low-pass filtering with downsampling effected thereby with a first conversion factor and averaging, wherein the error-free oscillation signal phase differences (Δφ S,M1 ) are calculated without contained phase errors due to an averaged-out first measuring channel phase difference (Δφ M1 ); calculating averaged error-containing oscillation signal phase differences (Δφ S,M2 ) using a second measuring channel pair with a second measuring channel phase difference (Δφ M2 ) from the oscillation signals by analog/digital conversion, phase detection, digital low-pass filtering with downsampling effected thereby with a second conversion factor and averaging, wherein the averaged error-containing oscillation signal phase differences (Δφ S,M2 ) contains phase error in the form of the second measuring channel phase difference (Δφ M2 ); determining error-containing oscillation signal phase differences (Δφ S,M3 ) with included phase error using a third measuring channel pair with negligible measuring channel phase difference, the oscillation signal phase positions of the second measuring channel pair measured after the phase detection in the second measuring channel pair are captured and either by continuous low-pass filtering without downsampling or by low-pass filtering with downsampling with a third conversion factor, wherein the third conversion factor is smaller or larger than the first conversion factor and the second conversion factor, wherein the error-containing oscillation signal phase differences (Δφ S,M3 ) with included phase error are determined on the basis of the second measuring channel phase difference (Δφ M2 ); determining the second measuring channel phase difference (Δφ M2 ) by difference formation from the averaged error-containing oscillation signal phase differences (Δφ S,M2 ) with contained phase error of the second measuring channel pair and the error-free oscillation signal phase differences (Δφ S,M1 ) without contained phase error of the first measuring channel pair; obtaining error-free oscillation signal phase differences (Δφ S ) without contained phase error by subtractng the determined second measuring channel phase difference (Δφ M2 ) from the error-containing oscillation signal phase differences (Δφ S,M3 ) of the third measuring channel pair; and using the error-free oscillation signal phase differences (Δφ S ) without contained phase error as a basis for determining the mass flow rate. 2. The method according to claim 1 , wherein the determination of the error-free oscillation signal phase differences (Δφ M1 ) using the first measuring channel pair is implemented in such a way that the oscillation signals are processed using the first measuring channel pair with a first measuring channel and a second measuring channel and with a first measuring channel phase difference (Δφ M1 ) between the first measuring channel and the second measuring channel, wherein the first oscillation signal and the second oscillation signal in the first measuring channel pair are routed on the input side alternately via the first measuring channel and the second measuring channel using a first channel switch, the oscillation signals are either sampled downstream of the channel switch by at least one analog/digital converter at a first sampling rate and the sampled oscillation signals are fed back to their original measuring channel or the oscillation signals after the channel switch are fed to their original measuring channel using a second channel switch and are then sampled by at least one analog/digital converter at a first sampling rate, and first measured oscillation signal phase positions are determined from the sampled first oscillation signals using at least one phase detector and second measured oscillation signal phase positions are determined from the sampled second oscillation signals, a low-pass filtered first oscillation signal phase position and a low-pass filtered second oscillation signal phase position are determined from a plurality of the first and second measured oscillation signal phase positions obtained in a respective position of the channel switches using at least one digital filter with low-pass characteristic, so that a downsampling with the first conversion factor is effected in the first measuring channel pair, and, from temporally corresponding low-pass-filtered oscillation signal phase positions in each case in one position of the channel switch, corresponding error-containing oscillation signal phase differences with contained phase error are determined on the basis of the first measuring channel phase difference (Δφ M1 ) and error-free oscillation signal phase differences (Δφ S,M1 ) without contained phase error are calculated by averaging from a plurality of error-containing oscillation signal phase differences with contained phase error. 3. The method according to claim 1 , wherein the determination of the averaged error-containing oscillation signal phase differences (Δφ S,M2 ) using the second measuring channel pair is implemented in that the oscillation signals are processed using the second measuring channel pair with a first measuring channel and a second measuring channel and with a second measuring channel phase difference (Δφ M2 ) between the first measuring channel and the second measuring channel, wherein the first oscillation signal and the second oscillation signal are sampled by at least one analog/digital converter at a first sampling rate and first measured oscillation signal phase positions are determined from the sampled first oscillation signals by at least one phase detector and second measured oscillation signal phase positions are determined from the sampled second oscillation signals, a low-pass filtered first oscillation signal phase position and a low-pass filtered second oscillation signal phase position are determined from a plurality of the first and second measured oscillation signal phase positions obtained in the second measuring channel pair during setting of the channel switches of the first measuring channel pair by means of at least one digital filter having a low-pass characteristic, so that downsampling is thus effected with the second conversion factor in the second measuring channel pair and corresponding error-containing oscillation signal phase differences with contained phase error are determined from temporally corresponding low-pass-filtered oscillation signal phase positions on the basis of the second measuring channel phase difference (Δφ M2 ), and averaged error-containing oscillation signal phase di