Electromagnetic field detector

The invention claimed is: 1. An electromagnetic field detector comprising: a first optical signal interface configured to receive, from one or more remote optical sources, a first optical signal; an electromagnetic field transmitter configured to transmit a local oscillator electromagnetic field generated from the first optical signal, the electromagnetic field transmitter comprising: a photocurrent generator configured to generate a photocurrent from the first optical signal; and an antenna interface configured to supply the photocurrent to an antenna to transmit the local oscillator electromagnetic field; a second optical signal interface configured to receive, from the one or more remote optical sources, a probe optical signal and a coupling optical signal; and a transmission medium configured to be excited by the probe optical signal and further excited by the coupling optical signal, wherein the probe optical signal has a probe frequency set to excite electrons of the transmission medium to a first excited state and the coupling optical signal has a coupling frequency set to excite electrons of the transmission medium to a predetermined Rydberg state so as to induce an Electromagnetic Induced Transparency, EIT, effect, wherein the transmission medium is further configured to receive a phase-modulated electromagnetic field from a remote transmitter and the local oscillator electromagnetic field such that the combination of the phase-modulated electromagnetic field and the local oscillator electromagnetic field causes a change in the probe optical signal from which a phase state of the phase-modulated electromagnetic field can be detected. 2. An electromagnetic field detector as claimed in claim 1 , wherein the first optical signal interface is further configured to receive a second optical signal from the one or more remote optical sources, and the photocurrent generator is configured to generate the photocurrent by mixing the first and second optical signals. 3. An electromagnetic field detector as claimed in claim 1 , wherein the local oscillator electromagnetic field and the phase-modulated electromagnetic field are synchronised. 4. An electromagnetic field detector as claimed in claim 1 , wherein the first optical signal has a wavelength in one of the O-band, E-band, S-band, C-band, L-band, and U/XL-band. 5. An electromagnetic field detector as claimed in claim 2 , wherein the second optical signal has a wavelength in one of the O-band, E-band, S-band, C-band, L-band, and U/XL-band. 6. An electromagnetic field detector as claimed in claim 1 , wherein the local oscillator electromagnetic field is dual-polarised. 7. An electromagnetic field detector as claimed in claim 1 , further comprising: a first module comprising the first optical signal interface and the electromagnetic field transmitter; and a second module comprising the second optical signal interface and the transmission medium. 8. An electromagnetic field detector as claimed in claim 7 , wherein the first module and second module are either embodied in a single housing or embodied in respective housings. 9. An electromagnetic field detector as claimed in either claim 7 , wherein the second module is one of a plurality of second modules, each second module comprising: a respective second optical signal interface configured to receive, from the one or more remote optical sources, the probe optical signal and the coupling optical signal, and a respective transmission medium configured to be excited by the probe optical signal and further excited by the coupling optical signal, wherein the probe optical signal has a probe frequency set to excite electrons of the transmission medium to a first excited state and the coupling optical signal has a coupling frequency set to excite electrons of the respective transmission medium to a predetermined Rydberg state so as to induce an Electromagnetic Induced Transparency, EIT, effect, wherein the respective transmission medium is further configured to receive a phase-modulated electromagnetic field from the remote transmitter and the local oscillator electromagnetic field from the electromagnetic field transmitter of the first module such that the combination of the phase-modulated electromagnetic field and the local oscillator electromagnetic field causes a change in the probe signal from which a phase state of the phase-modulated electromagnetic field can be detected. 10. An electromagnetic field detector as claimed in claim 9 , wherein the first module is one of a plurality of first modules, each first module comprising: a respective first optical signal interface configured to receive, from the one or more remote optical sources, the first optical signal, and a respective electromagnetic field transmitter configured to transmit a local oscillator electromagnetic field generated from the first optical signal, wherein each first module of the plurality of first modules is associated with a second module of the plurality of second modules such that the local oscillator electromagnetic field transmitted by the respective electromagnetic field transmitter of that first module is received at the transmission medium of the associated second module. 11. A system comprising: an electromagnetic field detector as claimed in claim 1 ; one or more optical sources, remote from the electromagnetic field detector, configured to generate the first optical signal, the probe optical signal and the coupling optical signal, and communicate the first optical signal, probe optical signal and coupling optical signal to the electromagnetic field detector. 12. A system as claimed in claim 11 , being part of a telecommunications network, wherein the one or more optical sources is configured to receive a network-distributed synchronisation signal, and the one or more optical sources is configured to synchronise the first optical signal based on the synchronisation signal. 13. A system as claimed in claim 12 , wherein the phase-modulated electromagnetic field is synchronised with the network-distributed synchronisation signal. 14. A system as claimed in claim 11 , further comprising a master clock and a transmitter configured to communicate a synchronisation signal, derived from the master clock, to the remote transceiver, wherein the first optical signal is synchronised to the synchronisation signal. 15. A system as claimed in claim 11 , further comprising an optical telecommunications network, wherein the first optical signal, probe optical signal and coupling optical signal are communicated to the electromagnetic field detector via the optical telecommunications network. 16. A method of operating an electromagnetic field detector, the electromagnetic detector having a transmission medium, the method comprising the steps of: receiving, from one or more remote optical sources, a first optical signal; generating a photocurrent from the first optical signal; transmitting a local oscillator electromagnetic field generated from the first optical signal by supplying the photocurrent to an antenna; receiving, from the one or more remote optical sources, a probe optical signal and a coupling optical signal, wherein the transmission medium is excited by the probe optical signal having a probe frequency set to excite electrons of the transmission medium to a first excited state, and wherein the transmission medium is further excited by the coupling optical signal having a coupling frequency set to excite electrons of the transmission medium to a predetermined Rydberg state so as to induce an Electromagnetic Ind