[摘要] Processor manufacturers have turned to parallelism to continue to improve processor performance, and the bandwidth demands of manycore systems are rising. Silicon photonics can lower the energy-per-bit of core-to-core and core-to-memory interconnects while simultaneously alleviating bandwidth bottlenecks. In this work, methods of controlling the amount of charge entering the diode structure of a photonic modulator are investigated to achieve high energy efficiency in a constrained monolithic process. Two digital modulator topologies are simulated, fabricated and tested. One circuit topology, intended to drive a carrier-injection-based ring modulator, uses a digital push-pull topology with preemphasis to reduce the energy-per-bit and to prevent the ring;;s optical passband from shifting to the next optical channel. The second circuit topology drives a depletion-mode modulator device for high energy efficiency and speed. High-level system modeling is addressed, as well as practical considerations such as packaging. This work marks the first monolithic transceiver in a zero-change CMOS process, and the most energy-efficient monolithically-integrated modulator in a sub-100 nm CMOS process.