Optical modulator having Mach-Zehnder diodes of reduced length

What is claimed is: 1. A Mach-Zehnder modulator (MZM) comprising: an MZM input coupled to an input of a first optical coupler; a first optical path coupled to a first output of the first optical coupler, the first optical path comprising a first diode coupled to a first voltage signal node and configured to modify a phase of a first light signal transmitted through the first optical path; a second optical path coupled to a second output of the first optical coupler, the second optical path comprising a second diode coupled to a second voltage signal node and configured to modify a phase of a second light signal transmitted through the second optical path, wherein a first voltage signal carried on the first voltage signal node alternates between a forward biasing voltage level and a reverse biasing voltage level, and wherein a second voltage signal carried on the second voltage signal node alternates between a reverse biasing voltage level and a forward biasing voltage level; a further diode positioned in the first optical path and configured to introduce a phase shift to the first light signal; a second optical coupler comprising a first input and a second input, wherein the first optical path is coupled to the first input of the second optical coupler, and wherein the second optical path is coupled to the second input of the second optical coupler; and an MZM output coupled to a first output of the second optical coupler. 2. The MZM of claim 1 , further comprising a drive circuit coupled to the first and second voltage signal nodes and configured to generate the first and second voltage signals, wherein the drive circuit is configured to generate the forward biasing voltage level to be higher than o V and lower than a threshold voltage of the first and second diodes. 3. The MZM of claim 1 , wherein the first and second optical paths are arranged such that, in the absence of the first and second voltage signals, the further diode provides the only phase variation, introduced by the first and second optical paths, between the first and second light signals. 4. The MZM of claim 1 , wherein the first and second diodes comprise high speed phase modulation (HSPM) diodes and the further diode comprises a P-intrinsic-N phase modulation (PINPM) diode. 5. The MZM of claim 1 , wherein the further diode is configured to introduce a phase shift of between 10 and 80°. 6. The MZM of claim 1 , wherein the further diode is configured to introduce a phase shift of between 10 and 65°. 7. The MZM of claim 1 , wherein each of the first and second diodes has a length of between 200 and 1100 μm. 8. The MZM of claim 1 , wherein the further diode has a length of between 50 and 400 μm. 9. The MZM of claim 1 , further comprising a bias voltage generator coupled to the further diode. 10. An optical link comprising: the MZM of claim 1 ; and an optical channel coupled to the MZM output. 11. The MZM of claim 1 , further comprising: a second further diode positioned in the second optical path and configured to introduce a phase shift of the second light signal, wherein the phase shift to the second light signal is substantially equal and opposite to the phase shift of the first light signal. 12. The MZM of claim 9 , wherein the bias voltage generator is configured to generate a biasing voltage for controlling the phase shift introduced by the further diode. 13. The MZM of claim 12 , wherein the bias voltage generator is configured to generate the biasing voltage based on an output signal of a second output of the second optical coupler. 14. The MZM of claim 12 , wherein the bias voltage generator is configured to generate the biasing voltage based on an output signal of the first output of the second optical coupler. 15. A Mach-Zehnder modulator (MZM) comprising: a first optical path; a second optical path; a first diode located in the first optical path and coupled to a first voltage signal node, wherein the first diode is designed to have a first response time; a second diode located in the second optical path and coupled to a second voltage signal node, wherein the second diode is designed to have a second response time; a third diode located in the first optical path and coupled to a bias voltage node, wherein the third diode is designed to have a third response time that is slower than the first and second response times; and an optical coupler with a first input coupled to the first optical path and a second input coupled to the second optical path. 16. The MZM of claim 15 , wherein a first voltage signal carried on the first voltage signal node and a second voltage signal carried on the second voltage signal node each vary between a reverse biasing voltage level and a forward biasing voltage level. 17. The MZM of claim 15 , wherein the first and second diodes comprise high speed phase modulation (HSPM) diodes and the third diode comprises a P-intrinsic-N phase modulation (PINPM) diode. 18. The MZM of claim 15 , wherein the third diode is configured to introduce a phase shift of between 10 and 65°. 19. The MZM of claim 15 , wherein each of the first and second diodes has a length of between 200 and 1100 μm and wherein the third diode has a length of between 50 and 400 μm. 20. A method of optical modulation comprising: applying a first light signal to a first optical path that includes a first diode of a Mach-Zehnder modulator and a further diode; applying a second light signal to a second optical path that includes a second diode of the Mach-Zehnder modulator; introducing a phase shift in the first light signal by biasing the further diode; modifying a phase of the first light signal by applying a first voltage signal to the first diode, wherein the first voltage signal alternates between a reverse biasing voltage level and a forward biasing voltage level; modifying a phase of the second light signal by applying a second voltage signal to the second diode, wherein the second voltage signal alternates between the reverse biasing voltage level and the forward biasing voltage level; and combining the first and second light signals. 21. The method of claim 20 , wherein introducing the phase shift in the first light signal comprises biasing the further diode with a bias voltage determined by a calibration procedure. 22. The method of claim 20 , wherein the first and second diodes have a faster response time as compared to the further diode. 23. The method of claim 20 , wherein introducing the phase shift in the first light signal comprises introducing a phase shift of between 10 and 65°.