Superconducting transmission driver system

What is claimed is: 1. A superconducting transmission driver system comprising: a latching gate stage comprising at least one Josephson junction configured to switch from an off state to an oscillating voltage state to provide an oscillating voltage at a control node in response to a single flux quantum (SFQ) pulse received at an input; and a low-pass filter stage coupled to the control node and configured to convert the oscillating voltage to a pulse signal to be transmitted over a transmission line. 2. The system of claim 1 , wherein the latching gate comprises a self-reset stage coupled to the control node and being configured to switch the at least one Josephson junction from the oscillating voltage state to the off state after a predetermined duration of time to reset the latching gate stage. 3. The system of claim 2 , wherein the self-reset stage is configured as an inductor-resistor (LR) low-pass filter configured to provide damping of the oscillating voltage to switch the at least one Josephson junction from the oscillating voltage state to the off state based on a time constant of the LR low-pass filter corresponding to the predetermined duration of time. 4. The system of claim 2 , wherein the latching gate stage is configured to switch the at least one Josephson junction from the off state to the oscillating voltage state in response to the SFQ pulse received at the input and a DC bias current, wherein the self-reset stage is arranged as interconnecting the control node and a source of the DC bias current. 5. The system of claim 1 , wherein the at least one Josephson junction is unshunted to switch from the off state to the oscillating voltage state in response to the SFQ pulse received at the input. 6. The system of claim 1 , wherein the at least one Josephson junction comprises a first Josephson junction that is coupled to the control node via a first inductor and a second Josephson junction that is coupled to the control node via a second inductor, wherein the first Josephson junction is configured to trigger in response to the SFQ pulse to switch to the oscillating voltage state, and wherein the second Josephson junction is configured to trigger in response to the first Josephson junction switching to the oscillating voltage state to likewise switch to the oscillating voltage state. 7. The system of claim 1 , further comprising a reciprocal quantum logic (RQL) Josephson transmission line (JTL) that is configured to provide the SFQ pulse to the input as an RQL pulse comprising a positive fluxon and a negative fluxon, wherein the latching gate system is configured to reject the negative fluxon. 8. The system of claim 7 , wherein the latching gate system comprises an input Josephson junction that is arranged to trigger in response to the negative fluxon to substantially cancel the negative fluxon at the control node. 9. An inter-chip transmission system comprising the superconducting transmission driver system of claim 1 , the inter-chip transmission system further comprising: a receiver system configured to receive the pulse signal and to convert the pulse signal into a SFQ pulse; wherein the transmission line is configured to propagate the pulse signal between the superconducting transmission driver system and the receiver system. 10. The inter-chip transmission system of claim 9 , wherein the receiver system is configured as an RQL receiver system, the receiver system further comprising: a first Josephson transmission line (JTL) configured to convert the pulse signal to a positive fluxon; and a second JTL interconnecting an output of the first JTL and ground and being configured to generate a negative fluxon in response to the positive fluxon to generate an RQL pulse. 11. A superconducting transmission driver system comprising: a latching gate stage comprising at least one Josephson junction configured to switch from an off state to an oscillating voltage state to provide an oscillating voltage at a control node in response to a single flux quantum (SFQ) pulse received at an input, wherein the latching gate stage comprises a self-reset stage coupled to the control node and being configured to switch the at least one Josephson junction from the oscillating voltage state to the off state after a predetermined duration of time to reset the latching gate stage; and a low-pass filter stage coupled to the control node and configured to convert the oscillating voltage to a pulse signal to be transmitted over a transmission line. 12. The system of claim 11 , wherein the self-reset stage is configured as an inductor-resistor (LR) low-pass filter configured to provide damping of the oscillating voltage to switch the at least one Josephson junction from the oscillating voltage state to the off state based on a time constant of the LR low-pass filter corresponding to the predetermined duration of time. 13. The system of claim 11 , wherein the at least one Josephson junction is unshunted to switch from the off state to the oscillating voltage state in response to the SFQ pulse received at the input. 14. The system of claim 11 , wherein the at least one Josephson junction comprises a first Josephson junction that is coupled to the control node via a first inductor and a second Josephson junction that is coupled to the control node via a second inductor, wherein the first Josephson junction is configured to trigger in response to the SFQ pulse to switch to the oscillating voltage state, and wherein the second Josephson junction is configured to trigger in response to the first Josephson junction switching to the oscillating voltage state to likewise switch to the oscillating voltage state. 15. The system of claim 11 , further comprising a reciprocal quantum logic (RQL) Josephson transmission line (JTL) that is configured to provide the SFQ pulse to the input as an RQL pulse comprising a positive fluxon and a negative fluxon, wherein the latching gate system is configured to reject the negative fluxon. 16. The system of claim 15 , wherein the latching gate system comprises an input Josephson junction that is arranged to trigger in response to the negative fluxon to substantially cancel the negative fluxon at the control node. 17. An inter-chip transmission system comprising: a superconducting transmission driver system comprising: a latching gate stage comprising at least one Josephson junction configured to switch from an off state to an oscillating voltage state to provide an oscillating voltage at a control node in response to a single flux quantum (SFQ) pulse received at an input; and a low-pass filter stage coupled to the control node and configured to convert the oscillating voltage to a pulse signal to be transmitted over a transmission line; a receiver system configured to receive the pulse signal and to convert the pulse signal into a SFQ pulse; and a transmission line configured to propagate the pulse signal between the superconducting transmission driver system and the receiver system. 18. The system of claim 17 , wherein the latching gate comprises a self-reset stage comprising an inductor-resistor (LR) low-pass filter coupled to the control node and being configured to provide damping of the oscillating voltage to switch the at least one Josephson junction from the oscillating voltage state to the off state based on a time constant of the LR low-pass filter. 19. The system of claim 17 , wherein the at least one Josephson junction is unshunted to switch from the off state to the oscillating voltage state in response to the S