Imaging method and device for water/fat separation in magnetic resonance imaging

I claim as my invention: 1. An imaging method for water/fat separation in magnetic resonance imaging, said method comprising: operating a magnetic resonance scanner to execute a fast spin echo sequence based on the two-point Dixon method, in which an RF excitation pulse is emitted followed by at least one refocusing RF pulse; operating said magnetic resonance scanner in said fast spin echo sequence to activate, after each RF refocusing pulse, two readout gradients of the same polarity and one rephasing gradient of opposite polarity between said two readout gradients, with each of said two readout gradient producing an echo signal having an echo center; operating said magnetic resonance scanner in said fast spin echo sequence to cause each of said two readout gradients to be divided into a front part and a rear part by the echo center of the echo signal produced thereby, with a rear part of a front readout gradient of said two readout gradients being smaller in area than a front part thereof, and with a front part of a rear readout gradient of said two readout gradients being smaller in area than a rear part thereof; in a processor, subjecting each echo signal acquired to a fast Fourier transform, so as to reconstruct an image with water and fat in phase and an image with water and fat in opposed phases, wherein data of each echo signal is further subjected to a partial Fourier transform; and in said processor, subjecting the image with water and fat in phase and the image with water and fat in opposed phases to a water/fat separation algorithm, to obtain a pure water image and a pure fat image at an output of said processor. 2. The method as claimed in claim 1 , wherein of the two readout gradients corresponding to each refocusing RF pulse, the duration of the rear part of the front readout gradient is less than or equal to the duration of the front part thereof, and the duration of the front part of the rear readout gradient is less than or equal to the duration of the rear part thereof. 3. The method as claimed in claim 1 , wherein: of the two readout gradients and the rephasing gradient corresponding to each refocusing RF pulse, when the front readout gradient switches to the rephasing gradient, the front readout gradient rises from a first amplitude to a zero gradient value at a maximum rate of gradient change, and when the rephasing gradient switches to the rear readout gradient, the rear readout gradient falls from the zero gradient value to the first amplitude at the maximum rate of gradient change; and the rephasing gradient rises from the zero gradient value to a second amplitude at the maximum rate of gradient change, and falls from the second amplitude to the zero gradient value at the maximum rate of gradient change; or the rephasing gradient rises from the zero gradient value to a second amplitude at a rate of gradient change that is less than the maximum rate of gradient change, and falls from the second amplitude to the zero gradient value at the rate of gradient change that is less than the maximum rate of gradient change; or the rephasing gradient rises from the zero gradient value to a second amplitude along a first curve, and falls from the second amplitude to the zero gradient value along a second curve, wherein the first curve and the second curve are axisymmetric curves with the center of the rephasing gradient as an axis. 4. The method as claimed in claim 1 , wherein: of the two readout gradients and the rephasing gradient corresponding to each refocusing RF pulse, when the front readout gradient switches to the rephasing gradient, the front readout gradient rises from a first amplitude to a zero gradient value at a first rate of gradient change that is less than a maximum rate of gradient change, and when the rephasing gradient switches to the rear readout gradient, the rear readout gradient falls from the zero gradient value to the first amplitude at the first rate of gradient change; and the rephasing gradient rises from the zero gradient value to a second amplitude at the maximum rate of gradient change, and falls from the second amplitude to the zero gradient value at the maximum rate of gradient change; or the rephasing gradient rises from the zero gradient value to a second amplitude at a second rate of gradient change that is less than the maximum rate of gradient change, and falls from the second amplitude to the zero gradient value at the second rate of gradient change; or the rephasing gradient rises from the zero gradient value to a second amplitude along a first curve, and falls from the second amplitude to the zero gradient value along a second curve, wherein the first curve and the second curve are axisymmetric curves with the center of the rephasing gradient as an axis. 5. The method as claimed in claim 4 , wherein the second rate of gradient change is equal to the first rate of gradient change. 6. The method as claimed in claim 1 , wherein: of the two readout gradients and the rephasing gradient corresponding to each refocusing RF pulse, when the front readout gradient switches to the rephasing gradient, the front readout gradient rises from a first amplitude to a zero gradient value along a first curve, and when the rephasing gradient switches to the rear readout gradient, the rear readout gradient falls from the zero gradient value to the first amplitude along a second curve, wherein the first curve and the second curve are axisymmetric curves with the center of the rephasing gradient as an axis; and the rephasing gradient rises from the zero gradient value to a second amplitude at a maximum rate of gradient change, and falls from the second amplitude to the zero gradient value at the maximum rate of gradient change; or the rephasing gradient rises from the zero gradient value to a second amplitude at a rate of gradient change that is less than the maximum rate of gradient change, and falls from the second amplitude to the zero gradient value at the rate of gradient change that is less than the maximum rate of gradient change; or the rephasing gradient rises from the zero gradient value to a second amplitude along a third curve, and falls from the second amplitude to the zero gradient value along a fourth curve, wherein the third curve and the fourth curve are axisymmetric curves with the center of the rephasing gradient as an axis. 7. The method as claimed in claim 6 , wherein the third curve and the first curve are a centrosymmetric curve with its center at the point of the zero gradient value to which the front readout gradient rises, and the fourth curve and the second curve are a centrosymmetric curve with its center at the point of the zero gradient value at which the rear readout gradient begins. 8. The method as claimed in claim 3 , wherein the absolute values of the first amplitude and the second amplitude are the same. 9. The method as claimed in claim 1 , wherein the sampling window for each echo signal includes a platform period of the readout gradient corresponding to the echo signal; or the sampling window for each echo signal includes a platform period of the readout gradient corresponding to the echo signal and part or all of an edge period of the readout gradient. 10. The method as claimed in claim 1 , wherein the step of subjecting each echo signal acquired to an FFT so as to reconstruct an image with water and fat in phase and an image with water and fat in opposed phases comprises: converting an analog signal of each echo signal acquired to a digital signal; completing phase encoding and Fast Fourier Transform of the digital signal of each echo signal, so as to form complex image data for each echo signal and fill k-space with the same, wherein a readout lin