Milestones, hotspots and trends in the development of electric machines

As one of the greatest inventions of human beings, the electric machine (EM) has realized the mutual conversion between electrical energy and mechanical energy, which has essentially led humanity into the age of electrification and greatly promoted the progress and development of human society. This paper will briefly review the development of EMs in the past two centuries, highlighting the historical milestones and investigating the driving force behind it. With the innovation of theory, the progress of materials and the breakthrough of computer science and power electronic devices, the mainstream EM types has been continuously changing since its appearance. This paper will not only summarize the basic operation principle and performance characteristics of traditional EMs, but also that of the emerging types of EMs. Meanwhile, control and drive system, as a non-negligible part of EM system, will be complementarily introduced. Finally, due to the background of global emission reduction, industrial intelligentization and transportation electrification, EM industry will usher again in a golden period of development. Accordingly, several foreseeable future developing trends will be analyzed and summarized

Nanofabrication via laser interference lithography and integration of various optical systems for remote sensing applications

Nanophotonic devices help to manipulate light at nanometric scale through various optical phenomena in near infrared and visible regions of the electromagnetic spectrum. This research aims to present the fabrication, modelling, optical characterisation and real life applications of optical devices based on materials such as ink, soft polymer, gelatine, leuco dye and liquid crystals. Laser interference-based ablation is utilised to generate phase conjugate nanostructures on ink, gelatine based edible nanostructures for food decoration purposes, and flexible polymeric nanostructures on polydimethylsiloxane substrate to demonstrate their use for remote sensing applications. Replication of Cornercube Retroreflector array and diffusing surface is conducted in this research to construct flexible force and temperature sensors. CCRs are mainly exploited in this research due to their retroreflection property. Reflected light from CCRs is sent back towards the source through total internal reflection and is independent of the incident angle. A silver coated CCR is used to fabricate a 2D conjugate periodic gratings structure on ink coated glass substrate through Denisyuk reflection holography. Diffractive gratings (super prism) fabricated from simple mirror-based interference reflection have less features to manipulate as compared to the conjugate diffractive gratings made by using interference obtained from CCRs. Nanometric holographic CCR showed somewhat similar optical properties as shown by master centimetric CCR e.g. phase conjugation. Predictions through computational modelling were also in good agreement with the experimental (optical characterisation) results. CCR array structures are most commonly encountered in everyday life activities such as traffic signals, vehicle safety systems and nightwear clothing. The use of brittle optical devices is limited due to their rigidity. In this research, PDMS was used to replicate rigid CCRs array structures into a flexible form. Polymeric CCRs array was examined and compared to the stencil by utilising optical microscopy. Optical characterisations were performed under various mechanical and thermal stress levels. Optical properties dependent on structure’s dimension were tuned based on the external stimuli such as force. It is concluded in this study that polymeric optical structures have a potential to be employed in numerous sensing applications for stretch, temperature, pH, and humidity. Combination of CCRs and thermochromatic materials can yield remote temperature sensors based on active components. This research also demonstrates two different systems including liquid crystals and leuco dyes to record temperature changes within a region of interest. Glass based CCRs were coated with leuco dye and liquid crystals and were treated at various known temperatures under continuous monochromatic light illumination. Reflected power from thermochromatic CCR was tuned based on supplied temperature and was found to be dependent on the colour scheme. These novel systems may help to monitor environmental conditions such as temperature changes within hazardous areas, where human access is restricted. Finally, edible, flexible and multi-layered materials were engineered with photonic structures to examine the flexibility of Nd:YAG laser ablation in Denisyuk reflection mode. Fabricated structures were examined by scanning electron microscopy and optically characterised with monochromatic and broadband light sources. Various shapes of nanostructures were achieved by utilising provided parameters for fabrication. It is hence concluded that laser interference-based ablation is simple, fast, cost-effective and flexible technique to copy reflective objects in nanometric scale

Aerospace medicine and biology: A continuing bibliography with indexes (supplement 394)

This bibliography lists 71 reports, articles and other documents introduced into the NASA Scientific and Technical Information System during Nov. 1994. Subject coverage includes: aerospace medicine and physiology, life support systems and man/system technology, protective clothing, exobiology and extraterrestrial life, planetary biology, and flight crew behavior and performance

Development of Trigger and Control Systems for CMS

During the year of 2007, the Large Hadron Collider (LHC) and its four main detectors will begin operation with a view to answering the most pressing questions in particle physics. However before one can analyse the data produced to find the rare phenomena being looked for, both the detector and readout electronics must be thoroughly tested to ensure that the system will operate in a consistent way. The Compact Muon Solenoid (CMS) is one of the two general-purpose detectors at CERN. The tracking component of the design produces more data than any previous detector used in particle physics, with approximately ten million detector channels. The data from the detector is processed by the tracker Front End Driver (FED). The large data volume necessitated the development of a buffering and throttling system to prevent buffer overflow both on and off the detector. A critical component of this system is the APV emulator (APVe), which vetoes trigger decisions based on buffer status in the tracker. The commissioning of these components, along with a large part of the Timing, Trigger and Control (TTC) system is discussed, including the various modifications that were made to improve the robustness of the full system. Another key piece of the CMS electronics is the calorimeter trigger system, responsible for identifying âinteresting' physical events in a background of well-understood phenomena using calorimetric information. Calorimeter information is processed to identify various trigger objects by the Global Calorimeter Trigger (GCT). The first component of this system is the Source card, which has been developed to transfer data from the Regional Calorimeter Trigger (RCT) to the Leaf card, the processing engine of the GCT. The use of modern programmable logic with high speed optical links is discussed, emphasising its use for data concentration and the benefit it confers to the processing algorithms. Looking forward to Super-LHC, a possible addition to the CMS Level-1 trigger system is discussed, incorporating information from a new pixel detector with an alternative stacked geometry that allows the possibility of on-detector data rate reduction by means of a transverse momentum cut. A toy Monte Carlo was developed to study detector performance. Issues with high-speed reconstruction and the complications of on-detector data rate reduction are also discussed

Lunar terrain and reflectivity study Final report

Lunar landing trajectory, landing module electronics and Doppler radar, and probable landing sites modeled for ultrasonic simulatio

1-D broadside-radiating leaky-wave antenna based on a numerically synthesized impedance surface

A newly-developed deterministic numerical technique for the automated design of metasurface antennas is applied here for the first time to the design of a 1-D printed Leaky-Wave Antenna (LWA) for broadside radiation. The surface impedance synthesis process does not require any a priori knowledge on the impedance pattern, and starts from a mask constraint on the desired far-field and practical bounds on the unit cell impedance values. The designed reactance surface for broadside radiation exhibits a non conventional patterning; this highlights the merit of using an automated design process for a design well known to be challenging for analytical methods. The antenna is physically implemented with an array of metal strips with varying gap widths and simulation results show very good agreement with the predicted performance

Beam scanning by liquid-crystal biasing in a modified SIW structure

A fixed-frequency beam-scanning 1D antenna based on Liquid Crystals (LCs) is designed for application in 2D scanning with lateral alignment. The 2D array environment imposes full decoupling of adjacent 1D antennas, which often conflicts with the LC requirement of DC biasing: the proposed design accommodates both. The LC medium is placed inside a Substrate Integrated Waveguide (SIW) modified to work as a Groove Gap Waveguide, with radiating slots etched on the upper broad wall, that radiates as a Leaky-Wave Antenna (LWA). This allows effective application of the DC bias voltage needed for tuning the LCs. At the same time, the RF field remains laterally confined, enabling the possibility to lay several antennas in parallel and achieve 2D beam scanning. The design is validated by simulation employing the actual properties of a commercial LC medium

Automation and Control Architecture for Hybrid Pipeline Robots

The aim of this research project, towards the automation of the Hybrid Pipeline Robot (HPR), is the development of a control architecture and strategy, based on reconfiguration of the control strategy for speed-controlled pipeline operations and self-recovering action, while performing energy and time management. The HPR is a turbine powered pipeline device where the flow energy is converted to mechanical energy for traction of the crawler vehicle. Thus, the device is flow dependent, compromising the autonomy, and the range of tasks it can perform. The control strategy proposes pipeline operations supervised by a speed control, while optimizing the energy, solved as a multi-objective optimization problem. The states of robot cruising and self recovering, are controlled by solving a neuro-dynamic programming algorithm for energy and time optimization, The robust operation of the robot includes a self-recovering state either after completion of the mission, or as a result of failures leading to the loss of the robot inside the pipeline, and to guaranteeing the HPR autonomy and operations even under adverse pipeline conditions Two of the proposed models, system identification and tracking system, based on Artificial Neural Networks, have been simulated with trial data. Despite the satisfactory results, it is necessary to measure a full set of robot’s parameters for simulating the complete control strategy. To solve the problem, an instrumentation system, consisting on a set of probes and a signal conditioning board, was designed and developed, customized for the HPR’s mechanical and environmental constraints. As a result, the contribution of this research project to the Hybrid Pipeline Robot is to add the capabilities of energy management, for improving the vehicle autonomy, increasing the distances the device can travel inside the pipelines; the speed control for broadening the range of operations; and the self-recovery capability for improving the reliability of the device in pipeline operations, lowering the risk of potential loss of the robot inside the pipeline, causing the degradation of pipeline performance. All that means the pipeline robot can target new market sectors that before were prohibitive

Fast, Parallel Techniques for Time-Domain Boundary Integral Equations

This work addresses the question of the efficient numerical solution of time-domain boundary integral equations with retarded potentials arising in the problems of acoustic and electromagnetic scattering. The convolutional form of the time-domain boundary operators allows to discretize them with the help of Runge-Kutta convolution quadrature. This method combines Laplace-transform and time-stepping approaches and requires the explicit form of the fundamental solution only in the Laplace domain to be known. Recent numerical and analytical studies revealed excellent properties of Runge-Kutta convolution quadrature, e.g. high convergence order, stability, low dissipation and dispersion. As a model problem, we consider the wave scattering in three dimensions. The convolution quadrature discretization of the indirect formulation for the three-dimensional wave equation leads to the lower triangular Toeplitz system of equations. Each entry of this system is a boundary integral operator with a kernel defined by convolution quadrature. In this work we develop an efficient method of almost linear complexity for the solution of this system based on the existing recursive algorithm. The latter requires the construction of many discretizations of the Helmholtz boundary single layer operator for a wide range of complex wavenumbers. This leads to two main problems: the need to construct many dense matrices and to evaluate many singular and near-singular integrals. The first problem is overcome by the use of data-sparse techniques, namely, the high-frequency fast multipole method (HF FMM) and H-matrices. The applicability of both techniques for the discretization of the Helmholtz boundary single-layer operators with complex wavenumbers is analyzed. It is shown that the presence of decay can favorably affect the length of the fast multipole expansions and thus reduce the matrix-vector multiplication times. The performance of H-matrices and the HF FMM is compared for a range of complex wavenumbers, and the strategy to choose between two techniques is suggested. The second problem, namely, the assembly of many singular and nearly-singular integrals, is solved by the use of the Huygens principle. In this work we prove that kernels of the boundary integral operators $w_n^h(d)$ ($h$ is the time step and $t_n=nh$ is the time) exhibit exponential decay outside of the neighborhood of $d=nh$ (this is the consequence of the Huygens principle). The size of the support of these kernels for fixed $h$ increases with $n$ as $n^a,a<1$, where $a$ depends on the order of the Runge-Kutta method and is (typically) smaller for Runge-Kutta methods of higher order. Numerical experiments demonstrate that theoretically predicted values of $a$ are quite close to optimal. In the work it is shown how this property can be used in the recursive algorithm to construct only a few matrices with the near-field, while for the rest of the matrices the far-field only is assembled. The resulting method allows to solve the three-dimensional wave scattering problem with asymptotically almost linear complexity. The efficiency of the approach is confirmed by extensive numerical experiments

Proceedings of the Third International Mobile Satellite Conference (IMSC 1993)

Satellite-based mobile communications systems provide voice and data communications to users over a vast geographic area. The users may communicate via mobile or hand-held terminals, which may also provide access to terrestrial cellular communications services. While the first and second International Mobile Satellite Conferences (IMSC) mostly concentrated on technical advances, this Third IMSC also focuses on the increasing worldwide commercial activities in Mobile Satellite Services. Because of the large service areas provided by such systems, it is important to consider political and regulatory issues in addition to technical and user requirements issues. Topics covered include: the direct broadcast of audio programming from satellites; spacecraft technology; regulatory and policy considerations; advanced system concepts and analysis; propagation; and user requirements and applications