Optimising and evaluating designs for reconfigurable hardware

Growing demand for computational performance, and the rising cost for chip design and manufacturing make reconfigurable hardware increasingly attractive for digital system implementation. Reconfigurable hardware, such as field-programmable gate arrays (FPGAs), can deliver performance through parallelism while also providing flexibility to enable application builders to reconfigure them. However, reconfigurable systems, particularly those involving run-time reconfiguration, are often developed in an ad-hoc manner. Such an approach usually results in low designer productivity and can lead to inefficient designs. This thesis covers three main achievements that address this situation. The first achievement is a model that captures design parameters of reconfigurable hardware and performance parameters of a given application domain. This model supports optimisations for several design metrics such as performance, area, and power consumption. The second achievement is a technique that enhances the relocatability of bitstreams for reconfigurable devices, taking into account heterogeneous resources. This method increases the flexibility of modules represented by these bitstreams while reducing configuration storage size and design compilation time. The third achievement is a technique to characterise the power consumption of FPGAs in different activity modes. This technique includes the evaluation of standby power and dedicated low-power modes, which are crucial in meeting the requirements for battery-based mobile devices

Degradation in FPGAs: Monitoring, Modeling and Mitigation

This dissertation targets the transistor aging degradation as well as the associated thermal challenges in FPGAs (since there is an exponential relation between aging and chip temperature). The main objectives are to perform experimentation, analysis and device-level model abstraction for modeling the degradation in FPGAs, then to monitor the FPGA to keep track of aging rates and ultimately to propose an aging-aware FPGA design flow to mitigate the aging

Tehomuuntajan säädön toteutus FPGA:lla

High switching frequencies and control rates in switched-mode power supplies are hard to implement with microcontrollers. Very high clock frequency is required to execute complex control algorithms with high control rate. FPGA chips offer a solution with inherent parallel processing. In this thesis, the feasibility of implementing the control of a typical telecom power converter with FPGA is studied. Requirements for the control system partitioning are considered. The control of a resonant LLC converter is studied in detail and implemented in VHDL. As part of the controller, a high-resolution variable frequency PWM module and floating-point arithmetic modules are implemented. Finally, a complete VHDL simulation model is created and run in different conditions to verify the functionality of the design.Korkeat kytkentä- ja säätötaajuudet hakkuriteholähteissä ovat haastavia toteuttaa mikrokontrollereilla. Monimutkaiset säätöalgoritmit edellyttävät mikrokontrollereilta korkeaa kellotaajuutta. FPGA-teknologia mahdollistaa rinnakkaislaskennan, joka on etu säätösovelluksissa. Tässä työssä tutkitaan FPGA teknologian soveltumista tyypillisen telecom-tehomuuntajan säätöön. Työssä selvitetään säätöjärjestelmän partitiointia sekä toteutetaan LLC-muuntajan ja sen säätöjärjestelmän simulaatiomalli VHDL-kielellä. Säädön osana toteutetaan korkearesoluutioinen PWM-moduuli sekä liukulukuaritmetiikkamoduuleja

A novel control mechanism for hybrid 5-level DC-DC converter for higher switching frequency and lower voltage ripple

The introduction and development of hybrid DC-DC converters present a valuable opportunity in on-chip power management, as they combine the advantages of buck and switched-capacitor converters while alleviating shortcomings such as conversion efficiency and sizing requirements. In this paper, a new control methodology is presented for the recently developed 5-level hybrid DC-DC converter, which utilizes the Virtex 5 LX50T FPGA to drive the converter. This control method allows for a higher switching frequency of 1MHz and an improved conversion efficiency while also allowing for dynamic voltage control based on the desired output voltage. Simulations as well as a test circuit are used to illustrate the proper control functionality, with tabulated results that showcase the efficiency advantage over prior control methods as well as the buck and 3-level hybrid converters

Delay Measurements and Self Characterisation on FPGAs

This thesis examines new timing measurement methods for self delay characterisation of Field-Programmable Gate Arrays (FPGAs) components and delay measurement of complex circuits on FPGAs. Two novel measurement techniques based on analysis of a circuit's output failure rate and transition probability is proposed for accurate, precise and efficient measurement of propagation delays. The transition probability based method is especially attractive, since it requires no modifications in the circuit-under-test and requires little hardware resources, making it an ideal method for physical delay analysis of FPGA circuits. The relentless advancements in process technology has led to smaller and denser transistors in integrated circuits. While FPGA users benefit from this in terms of increased hardware resources for more complex designs, the actual productivity with FPGA in terms of timing performance (operating frequency, latency and throughput) has lagged behind the potential improvements from the improved technology due to delay variability in FPGA components and the inaccuracy of timing models used in FPGA timing analysis. The ability to measure delay of any arbitrary circuit on FPGA offers many opportunities for on-chip characterisation and physical timing analysis, allowing delay variability to be accurately tracked and variation-aware optimisations to be developed, reducing the productivity gap observed in today's FPGA designs. The measurement techniques are developed into complete self measurement and characterisation platforms in this thesis, demonstrating their practical uses in actual FPGA hardware for cross-chip delay characterisation and accurate delay measurement of both complex combinatorial and sequential circuits, further reinforcing their positions in solving the delay variability problem in FPGAs

Energy Optimization in Commercial FPGAs with Voltage, Frequency and Logic Scaling

This paper investigates the energy reductions possible in commercially available FPGAs configured to support voltage, frequency and logic scalability combined with power gating. Voltage and frequency scaling is based on in-situ detectors that allow the device to detect valid working voltage and frequency pairs at run-time while logic scalability is achieved with partial dynamic reconfiguration. The considered devices are FPGA-processor hybrids with independent power domains fabricated in 28 nm process nodes. The test case is based on a number of operational scenarios in which the FPGA side is loaded with a motion estimation core that can be configured with a variable number of execution units. The results demonstrate that voltage scalability reduces power by up to 60 percent compared with nominal voltage operation at the same frequency. The energy analysis show that the most energy efficiency core configuration depends on the performance requirements. A low performance scenario shows that serial computation is more energy efficient than the parallel configuration while the opposite is true when the performance requirements increase. An algorithm is proposed to combine effectively adaptive voltage/logic scaling and power gating in the proposed system and application

On-Chip Communication and Security in FPGAs

Innovations in Field Programmable Gate Array (FPGA) manufacturing processes and architectural design have led to the development of extremely large FPGAs. There has also been a widespread adaptation of these large FPGAs in cloud infrastructures and data centers to accelerate search and machine learning applications. Two important topics related to FPGAs are addressed in this work: on-chip communication and security. On-chip communication is quickly becoming a bottleneck in to- day’s large multi-million gate FPGAs. Hard Networks-on-Chip (NoC), made of fixed silicon, have been shown to provide low power, high speed, flexible on-chip communication. An iterative algorithm for routing pre-scheduled time-division-multiplexed paths in a hybrid NoC FPGA architecture is demonstrated in this thesis work. The routing algorithm is based on the well known Pathfinder algorithm, overcomes several limitations of a previous greedy implementation and successfully routes connections using a higher number of timeslots than greedy approaches. The new algorithm shows an average bandwidth improvement of 11% for unicast traffic and multicast traffic patterns. Regarding on-chip FPGA security, a recent study on covert channel communication in Xilinx FPGA devices has shown information leaking from long interconnect wires into immediate neighboring wires. This information leakage can be used by an attacker in a multi-tenant FPGA cloud infrastructure to non-invasively steal secret information from an unsuspecting user design. It is demonstrated that the information leakage is also present in Intel SRAM FPGAs. Information leakage in Cyclone-IV E and Stratix-V FPGA devices is quantified and characterized with varying parameters, and across different routing elements of the FPGAs