Size, Speed, and Power Analysis for Application-Specific Integrated Circuits Using Synthesis

An application-specific integrated circuit (ASIC) must not only provide the required functionality at the desired speed but it must also be economical. In the past, minimizing the size of the ASIC was sufficient to accomplish this goal. Today it is increasingly necessary that the ASIC also achieve minimum power dissipation or an optimal combination of speed, size and power, especially in communication and portable electronic devices. The research reported in this thesis describes the implementation of a Huffman encoder and a finite impulse response (FIR) filter using a hardware description language (HDL) and the testing of the corresponding register transfer level (RTL) for functionality. The RTL was targeted for two different libraries, TSMC-0.18 CMOS and the Xilinx Virtex V1000EHQ240-6. The RTL was synthesized and optimized for different sizes, speeds, and power by using the Synopsys Design Compiler, FPGA Compiler II, and Mentor Graphics Spectrum. Cadence place and route tools optimized area, delay, and power of post-layout stages for TSMC-0.18. Xilinx place and route tools were used for the Virtex V1000EHQ240-6. The various ASICs were produced and compared over a range of speed, area, and power. i

Measurement incompatibility cannot be stochastically distilled

We show that the incompatibility of a set of measurements cannot be increased by subjecting them to a filter, namely, by combining them with a device that post-selects the incoming states on a fixed outcome of a stochastic transformation. This result holds for several measures of incompatibility, such as those based on robustness and convex weight. Expanding these ideas to Einstein-Podolsky-Rosen steering experiments, we are able to solve the problem of the maximum steerability obtained with respect to the most general local filters in a way that allows for an explicit calculation of the filter operation. Moreover, our results generalize to nonphysical maps, i.e., positive but not completely positive linear maps.Comment: 12 pages, 1 figure, comments welcom

Association between actigraphy-derived physical activity and cognitive performance in patients with schizophrenia

An association between low levels of physical activity and impaired cognitive performance in schizophrenia has been proposed, but most studies have relied on self-report measures of activity. This study examined the association between actigraphy-derived physical activity and cognitive performance adjusting for multiple covariates in patients with schizophrenia. Patients with schizophrenia (n = 199) were recruited from chronic psychiatric wards, and 60 age-, sex- and body mass index-matched comparison participants were recruited from the staff of two hospitals and universities. Physical activity was assessed objectively for 7 days using an ActiGraph. Cognitive performance was assessed with the Cognitrone test from the Vienna Test System and the Grooved Pegboard Test. Demographic variables, metabolic parameters, positive and negative symptoms, duration of illness and hospitalization, and medication use were included as covariates. Pearson correlations and multivariable linear regressions were conducted to examine the associations between physical activity levels and cognitive performance. Patients with schizophrenia were less physically active and had poorer performance on attention/concentration and speed of processing than the comparison group. Patients with schizophrenia who spent more time in light physical activity showed better performance on attention/concentration (β = 0.198, p = 0.020) and speed of processing (β= −0.169, p = 0.048) tasks than those who were less active. Cognitive performance was also associated with moderate-vigorous physical activity, but the effect was no longer significant once light physical activity had been taken into account. This study provides evidence for a positive association between objectively measured light physical activity and cognitive performance in people with schizophrenia, after adjustment for multiple confounders

Compact Dual-Band Dipole Antenna with Asymmetric Arms for WLAN Applications

A dual-band dipole antenna that consists of a horn- and a C-shaped metallic arm is presented. Depending on the asymmetric arms, the antenna provides two −10 dB impedance bandwidths of 225 MHz (about 9.2% at 2.45 GHz) and 1190 MHz (about 21.6% at 5.5 GHz), respectively. This feature enables it to cover the required bandwidths for wireless local area network (WLAN) operation at the 2.4 GHz band and 5.2/5.8 GHz bands for IEEE 802.11 a/b/g standards. More importantly, the compact size (7 mm × 24 mm) and good radiating performance of the antenna are profitable to be integrated with wireless communication devices on restricted RF-elements spaces