Daniel Roggow scite author profile

Daniel Roggow

4Publications

10Citation Statements Received

92Citation Statements Given

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Iowa State University

Publications

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Real-time simulation of dynamic vehicle models using a high-performance reconfigurable platform

Monga

Roggow

Karkee

et al. 2015

Microprocessors and Microsystems

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A purely software-based approach for Real-Time Simulation (RTS) may have difficulties in meeting real-time constraints for complex physical model simulations. In this paper, we present a methodology for the design and im-plementationof RTS algorithms,basedontheuseof Field-ProgrammableGateArray(FPGA) technologytoimprove the response time of these models. Our methodology utilizes traditional hardware/ software co-design approaches to generate a heterogeneous architecture for an FPGA-based simulator. The hardware design was optimized such that it efficiently utilizes the parallel nature of FPGAs and pipelines the independent operations. Further enhancement is obtained through the use of custom accelerators for common non-linear functions. Since the systems we examined had relatively low response time requirements, our approach greatly simplifies the software components by porting the computationally complexregionsto hardware.We illustratethe partitioningofa hardware-based simulator design across dual FPGAs, initiateRTS usinga system input froma Hardware-in-the-Loop (HIL) framework, and use these simulation results from our FPGA-based platform to perform response analysis. The total simulation time, which includes the time required to receive the system input over a socket (without HIL), software initialization, hardware computation, and transferof simulation results backovera socket, showsa speedup of 2× as compared to a similar setup with no hardware acceleration. The correctness of the simulation output from the hardware has also been validated with the simulated results from the software-only design. AbstractA purely software-based approach for Real-Time Simulation (RTS) may have difficulties in meeting real-time constraints for complex physical model simulations. In this paper, we present a methodology for the design and implementation of RTS algorithms, based on the use of Field-Programmable Gate Array (FPGA) technology to improve the response time of these models. Our methodology utilizes traditional hardware/software co-design approaches to generate a heterogeneous architecture for an FPGA-based simulator. The hardware design was optimized such that it efficiently utilizes the parallel nature of FPGAs and pipelines the independent operations. Further enhancement is obtained through the use of custom accelerators for common non-linear functions. Since the systems we examined had relatively low response time requirements, our approach greatly simplifies the software components by porting the computationally complex regions to hardware. We illustrate the partitioning of a hardware-based simulator design across dual FPGAs, initiate RTS using a system input from a Hardware-in-the-Loop (HIL) framework, and use these simulation results from our FPGA-based platform to perform response analysis. The total simulation time, which includes the time required to receive the system input over a socket (without HIL), software initialization, hardware computation, and transfer of simulation results back over a sock...

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A project-based embedded systems design course using a reconfigurable SoC platform

Roggow

Uhing

Jones

et al. 2015

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Embedded systems are becoming increasingly complex, as typical system components, such as sensors and other specialized processors, are blended together with more traditional microprocessors to form complex systems-on-chips (SoCs). Teaching undergraduate students to understand concepts and technologies behind embedded systems is important in order to prepare these future engineers with the skills and expertise necessary for designing such complex systems. This paper describes an undergraduate course designed to introduce students to embedded system design concepts and challenges in an engaging and effective manner. Our course uses a combination of in-depth laboratory assignments and topical lectures to provide a unique hands-on education for students. Laboratory assignments utilize Avnet's ZedBoard platform, a development board built around Xilinx's Zynq-7000 SoC, and require students to solve a variety of embedded system challenges from a range of application domains. Overall, student feedback about the course has been positive.

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Real-time ellipse detection on an embedded reconfigurable system-on-chip

Roggow

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An FPGA Architecture for the Recovery of WPA/WPA2 Keys

Johnson

Roggow

Jones

et al. 2015

J CIRCUIT SYST COMP

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Wi-Fi protected access (WPA) has provided serious improvements over the now deprecated wired equivalent privacy (WEP) protocol. WPA, however, still has some flaws that allow an attacker to obtain the passphrase. One of these flaws is exposed when the access point (AP) is operating in the WPA personal mode. This is the most common mode, as it is the quickest and easiest to configure. This vulnerability requires the attacker to capture the traffic from the four-way handshake between the AP and client, and then have enough compute time to reverse the passphrase. Increasing the rate at which passphrases can be reversed reduces the amount of time required to construct a repository of service set identifiers (SSIDs) and passphrases, which can increase the chances an attack is successful, or, alternatively, reduce the difficulty of auditing a wireless network for security purposes. This work focuses on creating an field programmable gate array (FPGA)-based architecture to accelerate the generation of a WPA/WPA2 pairwise master key (PMK) lookup table (LUT) for the recovery of the passphrase, with special emphasis on the secure hash algorithm-1 (SHA-1) implementation. PMK generation relies heavily on SHA-1 hashing and, as this work shows, an optimized SHA-1 implementation can achieve up to a 40 × speedup over an unoptimized implementation when generating PMKs.

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Daniel Roggow

Real-time simulation of dynamic vehicle models using a high-performance reconfigurable platform

A project-based embedded systems design course using a reconfigurable SoC platform

Real-time ellipse detection on an embedded reconfigurable system-on-chip

An FPGA Architecture for the Recovery of WPA/WPA2 Keys

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