Digital-data mixing apparatus and digital-data processing system

The invention claimed is: 1. A method for generating, using an electronic component, an electromagnetic beam source, an electromagnetic beam modulator, a multiple scattering medium, and a receiver, random projections of a plurality of input digital-data blocks to a plurality of output digital data blocks, the method comprising: receiving, from the electronic component, the plurality of input digital data blocks, each input data block comprising at least n bits of input digital data; receiving, from the electromagnetic beam source, an electromagnetic beam; for each input digital data block, generating, by the electromagnetic beam modulator, a modulated electromagnetic beam by applying, at p transverse locations of a wavefront of the electromagnetic beam, p simultaneous modulations of at least one physical property of the electromagnetic beam, wherein the at least n bits of input digital data are converted into the p simultaneous modulations; scattering the modulated electromagnetic beam by multiple electromagnetic scattering through the multiple scattering medium to generate a scattered electromagnetic beam; converting the scattered electromagnetic beam into an output digital data block comprising at least m bits of output digital data by acquiring the at least m bits of output digital data at q distinct locations of a sensor area of the receiver that receives the scattered electromagnetic beam; and providing the at least m bits of output digital data. 2. The method according to claim 1 , wherein the modulated electromagnetic beam is a beam of coherent electromagnetic radiation. 3. The method according to claim 1 , wherein the at least one physical property is at least one of an amplitude, an intensity, a phase, and a polarization of the electromagnetic beam. 4. The method according to claim 1 , wherein scattering the electromagnetic beam is performed by passive scattering medium. 5. The method according to claim 1 , wherein scattering the electromagnetic beam comprises: receiving the modulated electromagnetic beam by an entry face of the multiple scattering medium; performing multiple electromagnetic scattering by a scattering body of the multiple scattering medium separating the entry face from an exit face of the multiple scattering medium; and transmitting the scattered electromagnetic beam by the exit face of the multiple scattering medium. 6. The method according to claim 1 , wherein the number n of bits of the input data blocks is lower than the number m of bits of the output data blocks. 7. A computing device for generating random projections of a plurality of input digital-data blocks into a plurality of output digital data blocks, wherein the computing device comprises a digital-data mixing apparatus: a plurality of conductive terminals that receive from an electronic component the plurality of input digital-data blocks, each input digital-data block comprising at least n bits of input digital data; an electromagnetic beam source that generates an electromagnetic beam; an electromagnetic beam modulator that generates a electromagnetic beam by applying, at p transverse locations of a wavefront of the electromagnetic beam, p simultaneous modulations of at least one physical property of the electromagnetic beam, wherein the at least n bits of input digital data are converted into p simultaneous modulations; a multiple scattering medium that scatters the modulated electromagnetic beam by multiple electromagnetic scattering through the multiple scattering medium to generate a scattered electromagnetic beam; a receiver that converts the scattered electromagnetic beam into an output digital data block, wherein the output digital data block has at least m bits of output digital data, wherein the at least m bits of output digital data are acquired at q distinct locations of a sensor area of the receiver; and a plurality of conductive terminals that provide to an electronic component the at least m bits of output digital data. 8. The computing device according to claim 7 , wherein the modulated electromagnetic beam is a beam of coherent electromagnetic radiation. 9. The computing device according to claim 7 , wherein the at least one physical property is at least one of an amplitude, an intensity, a phase, and a polarization of the electromagnetic beam. 10. The computing device according to claim 7 , wherein the electromagnetic beam modulator is a spatial light modulator, wherein the spatial light modulator comprises micro-mirrors or liquid crystals, and wherein the electromagnetic beam source comprises a laser. 11. The computing device according to claim 7 , wherein the electromagnetic scattering medium is a passive scattering medium. 12. The computing device according to claim 7 , wherein the multiple scattering medium is a transmission scattering medium comprising an entry face that receives the modulated electromagnetic beam and an exit face that transmits the scattered electromagnetic beam, the entry face and exit face being separated by a scattering body that performs multiple electromagnetic scattering. 13. The computing device according to claim 7 , wherein the multiple scattering medium remains still over a period of time of at least two minutes. 14. The computing device according to claim 7 , wherein the receiver comprises an image sensor. 15. The computing device according to claim 7 , wherein the number n of bits of the input data blocks is lower than the number m of bits of the output data blocks. 16. The computing device according to claim 7 , comprising at least one separate electronic component that provides the input digital data to the at least one digital-data mixing apparatus, and receives the output digital data from the at least one digital-data mixing apparatus. 17. The computing device according to claim 7 , wherein the computing device is connected to a computer configured to implement a digital data processing algorithm, wherein the computing device: receives from the computer the plurality of input digital-data blocks generated by the digital data processing algorithm; generates random projections of the plurality of input digital-data blocks into the plurality of output digital data blocks; and provides the output digital data blocks to the computer. 18. A method of implementing a digital data processing algorithm using an electronic component, an electromagnetic beam source, an electromagnetic beam modulator, a multiple scattering medium, and a receiver, wherein the digital data processing algorithm is in a group consisting of a statistical Machine Learning algorithm, a deep neural network based algorithm, an Extreme Learning Machine algorithm, a Randomized Numerical Linear Algebra algorithm and a Locally Sensitive Hashing algorithm the method comprising: generating random projections of a plurality of input digital-data blocks into a plurality of output digital data blocks, wherein generating the random projections of a plurality of input digital-data blocks into a plurality of output digital data blocks comprises: receiving, from the electronic component, the plurality of input digital data blocks, each input data block comprising at least n bits of input digital data; receiving, from the electromagnetic beam source, an electromagnetic beam; for each input digital data block, generating, by the electromagnetic beam modulator, a modulated electromagnetic beam by applying, at p transverse locations of a wavefront of the electromagnetic beam, p simultaneous modulations of at least one physical property