Method for imaging or spectroscopy with a non-linear interferometer

The invention claimed is: 1. Method for imaging and/or spectroscopy using an interferometer setup, comprising the steps i) generation of a first signal field s 1 and a first idler field i 1 , by pumping a first non-linear medium with a pump beam, such that the two fields are correlated, ii) illumination of an object with the first idler i 1 field, respectively by transmission and/or reflection, iii) generation of a second signal field s 2 and a second idler field i 2 , by pumping a spatial separate second non-linear medium with the pump beam, or by pumping the first non-linear medium a second time with the pump beam, such that the two fields are correlated, iv) combination of the first i 1 and second i 2 idler fields, such that the two fields are indistinguishable, and combination of the first s 1 and second s 2 signal fields, such that the two fields interfere, v) first measurement of the interfered signal field s 12 by a detection means, vi) one or more additional measurements of the interfered signal field s 12 by the detection means, wherein for each additional measurement in step vi) a phase shift α is generated in the interferometer setup, and the phase shift α is varied from measurement-to-measurement in a known manner, and wherein the first measurement in step v) and the one or more additional measurements in step vi) are all carried out within a stability time of the interferometer setup, and vii) calculation of a phase function Φ of the object out of the measurements from step v) and step vi) in order to get an image and/or a spectrum of the object. 2. The method according to claim 1 , wherein the phase shift α is created in the first signal field s 1 and/or in the second signal field s 2 and/or in the first idler field i 1 and/or in the second idler field i 2 and/or in the pump beam in front of the first non-linear medium, preferably in the first pump beam and/or in the pump beam in front of the second non-linear medium, preferably in the second pump beam and/or between the first and second signal fields i 1 and i 2 and/or between the first signal and idler fields s 1 and i 1 , and/or between the first and the second pump beams, and/or in the interfered signal field s 12 . 3. The method according to claim 1 , wherein the phase shift α is created by changing the path length of one or more field/s, and/or changing the wavelength of the first and/or second pump beam, and/or by thermal effects, and/or by spatial displacement or change of the optical path length in one or both interferometer arms. 4. The method according to claim 1 , wherein the phase shifts can be introduced by a translation of a mirror and/or a translation of an optical surface and/or a translation of a dichroic mirror, respectively movable by a piezo element, and/or by a fiber expander, and/or by tilting a plane-parallel plate, and/or by an optical frequency difference between two beams, preferably two pump beams and/or by the change of the polarization by an EOM and/or wave plates and/or a polarizing beam splitter and/or a polarizer, and/or by tilting a plane-parallel plate, and or by a rotation or movement of a birefringent plate. 5. The method according to claim 1 , wherein the phase of the setup in step v) is unknown and/or arbitrary. 6. The method according to claim 1 , wherein in step i) and/or step iii) the signal and idler fields are separated by a separation means in or behind the crystal or are separated due to the generation of the signal and idler fields in the non-linear medium, respectively separated due to the generation of the fields in a BBO crystal. 7. The method according to claim 1 , wherein in step v) and/or vi) the constructive and destructive interference is measured, respectively by a first and second detection means behind two output arms of an interference means, respectively a 50/50 beam splitter, respectively wherein the 50/50 beam splitter is the signal combining means. 8. The method according to claim 1 , wherein in step v) and/or vi) one detection means is used, wherein for each measurement a phase shift α is generated, or two or more detection means are used, wherein for each additional detection means the same or a separate phase shift α is generated. 9. Apparatus for imaging and/or spectroscopy using an interferometer setup, comprising a pump source to generate a pump beam, and a first signal s 1 and idler i 1 field generation means pumped by the pump beam, and a second signal s 2 and idler i 2 field generation means pumped by the pump beam, wherein the first and the second field generation means are two spatial separated non-linear media pumped by the pump beam, or one non-linear medium, pumped by the pump beam a first time to generate a first signal s 1 and idler i 1 field and pumped a second time to generate a second signal s 2 and idler i 2 field, and an object to be measured which is illuminated, respectively by transmission or reflection, by the first idler field i 1 , and a signal combining means to overlap the first signal s 1 and second signal s 2 fields, such that the two fields interfere, and an idler combining means to overlap the first idler i 1 and second idler i 2 fields, such that the two fields are indistinguishable, and a detection means to detect the intensity and/or phase of the interfered signal field, characterized in that, a phase shifter is arranged in the first signal s 1 field, and/or in the second signal s 2 field, and/or in the pump beam, and/or in the indistinguishable first and second signal fields s 1 and s 2 , wherein the phase shifter is adapted to introduce a phase shift α in the apparatus during the measurement in order to get an image and/or a spectrum of the object, and the phase shift α is varied during the measurement in a known manner. 10. Apparatus according to claim 9 , wherein the phase shifts can be introduced by a movable mirror and/or a movable optical surface and/or a movable dichroic mirror, respectively movable by a piezo element, and/or by a fiber expander, and/or by a tiltable plane-parallel plate, and/or by an optical frequency difference between two beams, preferably two pump beams and/or by the change of the polarization by an EOM and/or wave plates and/or a polarizing beam splitter and/or a polarizer, and/or by a tiltable plane-parallel plate, and/or by a rotatable or moveable birefringent plate. 11. Apparatus according to claim 9 , wherein the separation means and the signal combining means are arranged in a Mach-Zehnder interferometer configuration or a laser Fizeau interferometer configuration, or a Michelson-interferometer configuration. 12. Apparatus according to claim 11 , wherein the phase shift a is created within the interferometer. 13. Apparatus according to claim 9 , wherein the apparatus comprises a control device adapted to provide one of the methods above, wherein the control device is connected to the phase shifter and to the detection means. 14. A non-transient computer-readable medium having stored thereon a computer-readable program for executing a method for at least one of imaging or spectroscopy using an interferometer setup, the method comprising the steps of: i) generation of a first signal field s 1 and a first idler field i 1 , by pumping a first non-linear medium with a pump beam, such that the two fields are correlated, ii) illumination of an object with the first idler i 1 field, respectively by transmission and/or reflection, iii) generation of a second signal field s 2 and a second idler field i 2 , by pumping a spatial sepa