Timur V. Filippov

Superconductor Digital-RF Receiver Systems

Digital superconductor electronics has been experiencing rapid maturation with the emergence of smaller-scale, lower-cost communications applications which became the major technology drivers. These applications are primarily in the area of wireless communications, radar, and surveillance as well as in imaging and sensor systems. In these areas, the fundamental advantages of superconductivity translate into system benefits through novel Digital-RF architectures with direct digitization of wide band, high frequency radio frequency (RF) signals. At the same time the availability of relatively small 4K cryocoolers has lowered the foremost market barrier for cryogenically-cooled digital electronic systems. Recently, we have achieved a major breakthrough in the development, demonstration, and successful delivery of the cryocooled superconductor digital-RF receivers directly digitizing signals in a broad range from kilohertz to gigahertz. These essentially hybrid-technology systems combine a variety of superconductor and semiconductor technologies packaged with two-stage commercial cryocoolers: cryogenic Nb mixed-signal and digital circuits based on Rapid Single Flux Quantum (RSFQ) technology, room-temperature amplifiers, FPGA processing and control circuitry. The demonstrated cryocooled digital-RF systems are the worlds first and fastest directly digitizing receivers operating with live satellite signals in X-band and performing signal acquisition in HF to L-band at ∼30GHz clock frequencies.

Digital Channelizing Radio Frequency Receiver

HYPRES is developing a class of digital receivers featuring direct digitization at radio frequency (RF). Such a receiver consists of a wideband analog-to-digital converter (ADC) modulator and multiple digital channelizer units to extract different frequency bands-of-interest within the broad digitized spectrum. The single-bit oversampled data, from either a lowpass delta or bandpass delta-sigma modulator, are applied to one or more channelizers, each comprising digital in-phase and quadrature mixers and a pair of digital decimation filters. We perform channelization in two steps, the first at full ADC sampling clock frequency with rapid single flux quantum (RSFQ) digital circuits and the second at reduced (decimated) clock frequency with commercial field programmable gate array (FPGA) chips at room temperature. We have demonstrated lowpass and bandpass digital receivers by integrating an ADC modulator and a channelizer unit on the same chip at clock frequencies up to 20 GHz. These 1-cm2 single-chip digital-RF receivers contain over 10,000 Josephson junctions. The channelizing receiver approach can be extended to include multiple ADC modulators and multiple channelizer units on a multi-chip module.

A superconductor high-resolution ADC

This paper presents the development of an Analog-to-Digital Converter (ADC) based on a low-temperature superconductor (Nb) chip and room-temperature interface modules for applications in digital receivers for communications, radars, and electronic warfare. The ADC design, MATLAB/sup TM/ simulations, and experimental results of single- and two-tone tests are described.

Sensitivity of the balanced Josephson-junction comparator

The sensitivity of a balanced comparator composed of two overdamped Josephson junctions fed by single flux pulses is calculated, taking into account both thermal and quantum fluctuations. The results of the analysis are compared with those of recent experiments. Ultimate resolution of the balanced comparator with feasible junction parameters is estimated to be as high as approximately 50 pA/Hz/sup 1/2/ at 4 K and approximately 10 pA/Hz/sup 1/2/ at T to 0 K. Performance limits of the device are compared with those of its single-junction counterpart.

Superconducting High-Resolution Low-Pass Analog-to-Digital Converters

HYPRES has developed a high-resolution, dynamically programmable analog-to-digital converter (ADC) for radar and communications applications. The ADC uses the phase modulation-demodulation low-pass architecture and on-chip digital filtering. Detailed experimental results at 20 GHz clock frequency of the ADC chip fabricated with a 1 kA/cm2 Nb process are presented and discussed. In addition to the standard ADC configuration, different ADC modifications are described. In the multi-rate ADC, the modulator sampling frequency is the twice the clock frequency for the time-interleaved digital filter. In addition to the standard parallel-output ADC, a serial output ADC and its interface to room temperature electronics are developed. This serial ADC chip fabricated with the advanced HYPRES 4.5 kA/cm2 process operated up to 34 GHz clock. As a major step toward commercialization of superconducting electronics, an ADC chip was successfully packaged on a cryocooler where it showed reduced performance up to 11.52 GHz clock.

Progress in Design of Improved High Dynamic Range Analog-to-Digital Converters

We describe several improvements that are being pursued to improve the dynamic range of lowpass phase modulation-demodulation (PMD) analog-to-digital converters (ADC). The existing ADC has been tested at sampling frequencies up to 29.44 GHz; a 89.15 dB signal to noise ratio (SNR) is achieved for a 10 MHz sinusoidal input, with the noise being measured in a reference 10 MHz bandwidth in the decimated band. The first improved approach involves a multi-rate ADC where the modulator sampling frequency is increased in multiples of the decimation filter clock. We have tested the multi-rate ADCs at sampling frequencies up to 46.08 GHz and 29.44 GHz for chips fabricated using the 4.5 and 1 kA/cm2 fabrication processes respectively. For a single channel ADC, with a 9.92 MHz sinusoidal input, sampled at 29.44 GHz, the SNR is 83.93 dB in a reference 10 MHz bandwidth. The spur-free dynamic range (SFDR) is 95 dB. In another improved architecture, called the quarter-rate ADC, the modified quantizer quadruples the input dynamic range by distributing the input in a cyclical fashion to four output channels, each operating at a quarter of the fluxon transport rate. This enables quadrupling the synchronizer channels, providing an opportunity for up to 12 dB performance enhancement. A parallel counter following the multi-channel synchronizer converts the differential code to a multi-bit binary code, which is further processed by the decimation filter. A prototype version of this ADC with a two channel synchronizer, fabricated using the 4.5 kA/cm2 process, has been tested up to a sampling frequency of 25.6 GHz. For a 10 MHz sinusoidal input, the SNR is 82.54 dB, with the noise measured in a reference 10 MHz bandwidth. We are also designing a subranging ADC with two PMD front-ends. Simulation results promise greater than 20 dB performance enhancement.

Performance Advantages and Design Issues of SQIFs for Microwave Applications

We consider applications of SQIFs as amplifiers for gigahertz frequency range. SQIF-like structures are able to provide much higher dynamic range and linearity than a dc SQUID. We also analyse design limitations imposed by finite coupling inductances and stray capacitances. Possible ways of resolving design issues are discussed.

Serially Biased Components for Digital-RF Receiver

Reduction of total bias current using the serial biasing technique is required for RSFQ-based digital-RF receiver realization. This will have a major impact on reducing the size, weight and power consumption of the complete cryocooled receiver system. The approach is based on partitioning a homogeneous design into several isolated islands biased in series and transmitting SFQ pulses between islands, over moats through inductively-coupled driver-receiver-pairs (DRPs). Experimental data on testing of 100 DRPs connected in series are reported and bit-error-rate estimates are given. Our goal is to serially bias two sets of homogeneous circuit blocks in the digital-RF receiver design: (1) digital decimation filter (DDF) bit slices, and (2) output drivers. The correct operation of test chips containing four bit-slices of a second-order DDF, partitioned into 2 and 4 islands, are demonstrated. Results of 8 output drivers, serially biased on 2, 4, and 8 islands, are reported. Design issues of scaling to a digital-RF receiver, containing 18-20 DDF bit slices and 16 output drivers are discussed.

Microwave receivers with direct digitization

Superconductor analog-to-digital converters (ADCs) and ultrafast digital circuitry enable processing of microwave signals entirely in the digital domain. We have designed and demonstrated a wide variety of continuous-time bandpass delta-sigma modulators using Josephson junction comparators. Featuring sampling frequencies up to 30 GHz, single-chip digital receivers have been demonstrated by connecting a rapid single flux quantum (RSFQ) digital circuitry with these ADCs. These receiver chips, cooled to 4 K by cryogen-free refrigerators, have been used with room-temperature digital processors to demonstrate reception of microwave signals for X-band satellite communications and Link-16 data links. To date, the highest frequency of direct digitization is 21 GHz for satellite communication. We report recent advances in ADC design to obtain higher dynamic range.

Integration of a 4-Stage 4 K Pulse Tube Cryocooler Prototype With a Superconducting Integrated Circuit

A custom-designed laboratory prototype of a four-stage Stirling-type pulse tube cryocooler was recently developed by Lockheed Martin for niobium integrated circuits (ICs) operating close to 4 K. Basic system performance has been verified by integration with a Nb IC test chip, with cells that include a high-speed rapid single flux quantum (RSFQ) binary counter. For 650 W total compressor power, extended stable operation of the counter at T=4.5 K was demonstrated with a clock frequency up to 46 GHz, with 25 mW of excess cooling capacity on the coldest stage. The thermodynamic, electromagnetic, and mechanical performance are promising for the development of an improved compact cryocooler for practical superconducting electronic applications in fields such as wireless communications.