Method for measuring the frequency modulation of a laser source

The invention claimed is: 1. A method for measuring the modulation frequency f(t) of a laser source, the method comprising the following steps: modulating the laser source over a period T, with a modulation controller; in a given period T, carrying out a plurality of measurements of a beat light intensity between two arms of an interferometer located downstream of the laser source and able to introduce a delay τ between the two arms, said measurements being synchronized with the control of the modulation; and calculating the frequency f(t) from the plurality of measurements; wherein during each period T, f(t) varies, and over a plurality of periods T, the delay τ varies as a function of time, with Δτ>10% λ/c and Δτ/τ<0.01λ/c, where c is the speed of light and λ the wavelength of the source; and wherein the plurality of measurements are carried out at the time t i in a given period and reiterated at t i +kT, with k≤1 the delay τ having varied from one iteration to the next; and the frequency modulation is calculated from all of the reiterated measurements obtained under distinct interference conditions because of the variation in τ. 2. The method for measuring the modulation frequency f(t) of a laser source as claimed in claim 1 , wherein the frequency modulation is calculated from a covariance matrix using a plurality of measurements. 3. The method for measuring the modulation frequency f(t) of a laser source as claimed in claim 1 , wherein the calculation includes: organizing reiterated measurements that are homologous from one period to the next in the form of vectors x(t), 0≤t≤T; these vectors x(t) describing an elliptical cylinder, calculating the axis w 0 of the cylinder; and projecting, along the axis w 0 , onto a determined plane, this projection being parameterized by an angle that is a function of f(t). 4. The method for measuring the modulation frequency f(t) of a laser source as claimed in claim 3 , wherein function of f(t) of the angle is developed to the first order and in that the angle is proportional to f(t). 5. The method for measuring the modulation frequency f(t) of a laser source as claimed in claim 1 , wherein the period T is a few μs, and the delay τ varies over a duration varying from a few seconds to a few minutes. 6. A method for calibrating the frequency of the laser source of a lidar to a setpoint f 0 (t), which comprises the following steps: modulating the frequency of the laser source by means of a preset periodic control voltage U(t); defining a linear transformation between f(t) and U(t); calculating a first control voltage U 1 (t) from f 0 (t) and said linear transformation; i=1 and iterating the following steps: measuring the frequency f i (t) of the laser source as claimed in claim 1 ; calculating the error Δf i (t)=f i (t)−f 0 (t) and a correcting control voltage from Δf i (t) and said linear transformation; defining a new control voltage U i+1 (t) from the preceding control voltage U i (t) and the correcting control voltage; i=i+1. 7. The calibrating method as claimed in claim 6 , wherein the linear transformation between f(t) and U(t) is obtained by measuring the transfer function of the frequency modulation, which is designated the FTM. 8. The calibrating method as claimed in claim 6 , wherein the number of iterations is lower than 10. 9. A computer program stored on a non-transitory computer-readable storage medium, comprising code instructions allowing the steps of the method as claimed in claim 1 to be carried out when said program is executed on a computer. 10. A system for measuring the frequency modulation f(t) of a laser source that comprises: the laser source associated with a modulation controller; a two-arm interferometer with a delay line in one of the arms; a device for measuring beat signals generated by the interferometer; a unit for processing the measured signals; and a synchronizing device that is connected to the modulation controller and to the processing unit; wherein the processing unit is suitable for implementing the method as claimed in claim 1 . 11. The system for measuring frequency modulation as claimed in claim 10 , wherein the interferometer is of Mach-Zehnder or Michelson type. 12. The system for measuring frequency modulation as claimed in claim 10 , wherein the interferometer does not include any acousto-optical modulators. 13. The method for measuring the modulation frequency f(t) of a laser source as claimed in claim 1 , wherein the variation as a function of time of the delay τ is stimulated by means of a piezoelectric device.