Physical quantities and their units
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This document defines many fundamental physical quantities used across various domains of physics including mechanics, rotational mechanics, thermodynamics, and electromagnetism. It provides the name, definition, formula, units, and dimensions for quantities such as length, time, mass, velocity, acceleration, force, energy, charge, current, voltage, and others. It also notes that mass, energy, momentum, angular momentum, and charge are conserved in isolated systems according to physics conventions.
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This document summarizes key concepts in physics related to motion, forces, energy, and sound waves. It covers Newton's laws of motion, definitions of speed, velocity, and acceleration. It also discusses gravitational force, momentum, work, power, heat transfer, and the properties of sound waves including wavelength, frequency, and how the velocity of sound varies with temperature. Key figures discussed include Aristotle, Galileo, Newton, and their contributions to the study and understanding of motion and force.
Gravity and time
- The universe is made up of quantized space and time units
- Time ticks in quanta that slow down near masses, as mass curves space and time
- Gravity brings masses together to increase their combined mass and further slow the ticking of time
- This slowing of time lowers the power consumption of the combined masses
- The universe applies gravity to minimize power consumption by synchronizing the ticking of time across masses
WISWEC - A NEW CONCEPT FOR A WAVE ENERGY CONVERTER
The proposed wave energy converter consists of a floating tube filled with water and power units inside. As waves pass, the water level inside the tube fluctuates up and down, causing buoys attached to the power units to move. This motion is converted to electrical energy via gear systems and generators. The design aims for low cost production and maintenance to produce electricity at around €0.05/kWh. Key aspects are its modular structure, ability to withstand storms by sinking below waves, and potential organization into zig-zag farms for efficient energy capture and transmission. Experimental testing is needed to validate the power generation capabilities and viability of the concept.
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Outcome 2.1 & 2.2 identify and use internationally recognised (si) units of...
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原版制作(carleton毕业证书)卡尔顿大学毕业证硕士文凭原版一模一样
原版纸张【微信:741003700 】【(carleton毕业证书)卡尔顿大学毕业证】【微信:741003700 】学位证,留信认证(真实可查,永久存档)offer、雅思、外壳等材料/诚信可靠,可直接看成品样本,帮您解决无法毕业带来的各种难题!外壳,原版制作,诚信可靠,可直接看成品样本。行业标杆!精益求精,诚心合作,真诚制作!多年品质 ,按需精细制作,24小时接单,全套进口原装设备。十五年致力于帮助留学生解决难题,包您满意。
本公司拥有海外各大学样板无数,能完美还原海外各大学 Bachelor Diploma degree, Master Degree Diploma
1:1完美还原海外各大学毕业材料上的工艺:水印,阴影底纹,钢印LOGO烫金烫银,LOGO烫金烫银复合重叠。文字图案浮雕、激光镭射、紫外荧光、温感、复印防伪等防伪工艺。材料咨询办理、认证咨询办理请加学历顾问Q/微741003700
留信网认证的作用:
1:该专业认证可证明留学生真实身份
2:同时对留学生所学专业登记给予评定
3:国家专业人才认证中心颁发入库证书
4:这个认证书并且可以归档倒地方
5:凡事获得留信网入网的信息将会逐步更新到个人身份内,将在公安局网内查询个人身份证信息后,同步读取人才网入库信息
6:个人职称评审加20分
7:个人信誉贷款加10分
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Remote Sensing and Computational, Evolutionary, Supercomputing, and Intellige...
Remote Sensing and Computational, Evolutionary, Supercomputing, and Intellige...University of Maribor
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Aleš Zamuda: Remote Sensing and Computational, Evolutionary, Supercomputing, and Intelligent Systems.
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3.Replacement Titration
4.Indirect Titration
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Deep Software Variability and Frictionless Reproducibility
Deep Software Variability and Frictionless ReproducibilityUniversity of Rennes, INSA Rennes, Inria/IRISA, CNRS
The ability to recreate computational results with minimal effort and actionable metrics provides a solid foundation for scientific research and software development. When people can replicate an analysis at the touch of a button using open-source software, open data, and methods to assess and compare proposals, it significantly eases verification of results, engagement with a diverse range of contributors, and progress. However, we have yet to fully achieve this; there are still many sociotechnical frictions.
Inspired by David Donoho's vision, this talk aims to revisit the three crucial pillars of frictionless reproducibility (data sharing, code sharing, and competitive challenges) with the perspective of deep software variability.
Our observation is that multiple layers — hardware, operating systems, third-party libraries, software versions, input data, compile-time options, and parameters — are subject to variability that exacerbates frictions but is also essential for achieving robust, generalizable results and fostering innovation. I will first review the literature, providing evidence of how the complex variability interactions across these layers affect qualitative and quantitative software properties, thereby complicating the reproduction and replication of scientific studies in various fields.
I will then present some software engineering and AI techniques that can support the strategic exploration of variability spaces. These include the use of abstractions and models (e.g., feature models), sampling strategies (e.g., uniform, random), cost-effective measurements (e.g., incremental build of software configurations), and dimensionality reduction methods (e.g., transfer learning, feature selection, software debloating).
I will finally argue that deep variability is both the problem and solution of frictionless reproducibility, calling the software science community to develop new methods and tools to manage variability and foster reproducibility in software systems.
Exposé invité Journées Nationales du GDR GPL 2024
THEMATIC APPERCEPTION TEST(TAT) cognitive abilities, creativity, and critic...
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hematic appreciation test is a psychological assessment tool used to measure an individual's appreciation and understanding of specific themes or topics. This test helps to evaluate an individual's ability to connect different ideas and concepts within a given theme, as well as their overall comprehension and interpretation skills. The results of the test can provide valuable insights into an individual's cognitive abilities, creativity, and critical thinking skillsApplied Science: Thermodynamics, Laws & Methodology.pdf
When I was asked to give a companion lecture in support of ‘The Philosophy of Science’ (https://shorturl.at/4pUXz) I decided not to walk through the detail of the many methodologies in order of use. Instead, I chose to employ a long standing, and ongoing, scientific development as an exemplar. And so, I chose the ever evolving story of Thermodynamics as a scientific investigation at its best.
Conducted over a period of >200 years, Thermodynamics R&D, and application, benefitted from the highest levels of professionalism, collaboration, and technical thoroughness. New layers of application, methodology, and practice were made possible by the progressive advance of technology. In turn, this has seen measurement and modelling accuracy continually improved at a micro and macro level.
Perhaps most importantly, Thermodynamics rapidly became a primary tool in the advance of applied science/engineering/technology, spanning micro-tech, to aerospace and cosmology. I can think of no better a story to illustrate the breadth of scientific methodologies and applications at their best.
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This presentation covers the content and information on "Cytokines " and their role in immune regulation .
The binding of cosmological structures by massless topological defects
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concentrically a number of such topological defects can establish a flat stellar or galactic rotation curve, and can also deflect
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如何办理(uvic毕业证书)维多利亚大学毕业证本科学位证书原版一模一样
原版纸张【微信:741003700 】【(uvic毕业证书)维多利亚大学毕业证】【微信:741003700 】学位证,留信认证(真实可查,永久存档)offer、雅思、外壳等材料/诚信可靠,可直接看成品样本,帮您解决无法毕业带来的各种难题!外壳,原版制作,诚信可靠,可直接看成品样本。行业标杆!精益求精,诚心合作,真诚制作!多年品质 ,按需精细制作,24小时接单,全套进口原装设备。十五年致力于帮助留学生解决难题,包您满意。
本公司拥有海外各大学样板无数,能完美还原海外各大学 Bachelor Diploma degree, Master Degree Diploma
1:1完美还原海外各大学毕业材料上的工艺:水印,阴影底纹,钢印LOGO烫金烫银,LOGO烫金烫银复合重叠。文字图案浮雕、激光镭射、紫外荧光、温感、复印防伪等防伪工艺。材料咨询办理、认证咨询办理请加学历顾问Q/微741003700
留信网认证的作用:
1:该专业认证可证明留学生真实身份
2:同时对留学生所学专业登记给予评定
3:国家专业人才认证中心颁发入库证书
4:这个认证书并且可以归档倒地方
5:凡事获得留信网入网的信息将会逐步更新到个人身份内,将在公安局网内查询个人身份证信息后,同步读取人才网入库信息
6:个人职称评审加20分
7:个人信誉贷款加10分
8:在国家人才网主办的国家网络招聘大会中纳入资料,供国家高端企业选择人才
Immersive Learning That Works: Research Grounding and Paths Forward
We will metaverse into the essence of immersive learning, into its three dimensions and conceptual models. This approach encompasses elements from teaching methodologies to social involvement, through organizational concerns and technologies. Challenging the perception of learning as knowledge transfer, we introduce a 'Uses, Practices & Strategies' model operationalized by the 'Immersive Learning Brain' and ‘Immersion Cube’ frameworks. This approach offers a comprehensive guide through the intricacies of immersive educational experiences and spotlighting research frontiers, along the immersion dimensions of system, narrative, and agency. Our discourse extends to stakeholders beyond the academic sphere, addressing the interests of technologists, instructional designers, and policymakers. We span various contexts, from formal education to organizational transformation to the new horizon of an AI-pervasive society. This keynote aims to unite the iLRN community in a collaborative journey towards a future where immersive learning research and practice coalesce, paving the way for innovative educational research and practice landscapes.
Describing and Interpreting an Immersive Learning Case with the Immersion Cub...
Current descriptions of immersive learning cases are often difficult or impossible to compare. This is due to a myriad of different options on what details to include, which aspects are relevant, and on the descriptive approaches employed. Also, these aspects often combine very specific details with more general guidelines or indicate intents and rationales without clarifying their implementation. In this paper we provide a method to describe immersive learning cases that is structured to enable comparisons, yet flexible enough to allow researchers and practitioners to decide which aspects to include. This method leverages a taxonomy that classifies educational aspects at three levels (uses, practices, and strategies) and then utilizes two frameworks, the Immersive Learning Brain and the Immersion Cube, to enable a structured description and interpretation of immersive learning cases. The method is then demonstrated on a published immersive learning case on training for wind turbine maintenance using virtual reality. Applying the method results in a structured artifact, the Immersive Learning Case Sheet, that tags the case with its proximal uses, practices, and strategies, and refines the free text case description to ensure that matching details are included. This contribution is thus a case description method in support of future comparative research of immersive learning cases. We then discuss how the resulting description and interpretation can be leveraged to change immersion learning cases, by enriching them (considering low-effort changes or additions) or innovating (exploring more challenging avenues of transformation). The method holds significant promise to support better-grounded research in immersive learning.
waterlessdyeingtechnolgyusing carbon dioxide chemicalspdf
The technology uses reclaimed CO₂ as the dyeing medium in a closed loop process. When pressurized, CO₂ becomes supercritical (SC-CO₂). In this state CO₂ has a very high solvent power, allowing the dye to dissolve easily.
Randomised Optimisation Algorithms in DAPHNE
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Aleš Zamuda: Randomised Optimisation Algorithms in DAPHNE .
Austrian-Slovenian HPC Meeting 2024 – ASHPC24, Seeblickhotel Grundlsee in Austria, 10–13 June 2024
https://ashpc.eu/
Authoring a personal GPT for your research and practice: How we created the Q...
Thematic analysis in qualitative research is a time-consuming and systematic task, typically done using teams. Team members must ground their activities on common understandings of the major concepts underlying the thematic analysis, and define criteria for its development. However, conceptual misunderstandings, equivocations, and lack of adherence to criteria are challenges to the quality and speed of this process. Given the distributed and uncertain nature of this process, we wondered if the tasks in thematic analysis could be supported by readily available artificial intelligence chatbots. Our early efforts point to potential benefits: not just saving time in the coding process but better adherence to criteria and grounding, by increasing triangulation between humans and artificial intelligence. This tutorial will provide a description and demonstration of the process we followed, as two academic researchers, to develop a custom ChatGPT to assist with qualitative coding in the thematic data analysis process of immersive learning accounts in a survey of the academic literature: QUAL-E Immersive Learning Thematic Analysis Helper. In the hands-on time, participants will try out QUAL-E and develop their ideas for their own qualitative coding ChatGPT. Participants that have the paid ChatGPT Plus subscription can create a draft of their assistants. The organizers will provide course materials and slide deck that participants will be able to utilize to continue development of their custom GPT. The paid subscription to ChatGPT Plus is not required to participate in this workshop, just for trying out personal GPTs during it.
在线办理(salfor毕业证书)索尔福德大学毕业证毕业完成信一模一样
学校原件一模一样【微信:741003700 】《(salfor毕业证书)索尔福德大学毕业证》【微信:741003700 】学位证,留信认证(真实可查,永久存档)原件一模一样纸张工艺/offer、雅思、外壳等材料/诚信可靠,可直接看成品样本,帮您解决无法毕业带来的各种难题!外壳,原版制作,诚信可靠,可直接看成品样本。行业标杆!精益求精,诚心合作,真诚制作!多年品质 ,按需精细制作,24小时接单,全套进口原装设备。十五年致力于帮助留学生解决难题,包您满意。
本公司拥有海外各大学样板无数,能完美还原。
1:1完美还原海外各大学毕业材料上的工艺:水印,阴影底纹,钢印LOGO烫金烫银,LOGO烫金烫银复合重叠。文字图案浮雕、激光镭射、紫外荧光、温感、复印防伪等防伪工艺。材料咨询办理、认证咨询办理请加学历顾问Q/微741003700
【主营项目】
一.毕业证【q微741003700】成绩单、使馆认证、教育部认证、雅思托福成绩单、学生卡等!
二.真实使馆公证(即留学回国人员证明,不成功不收费)
三.真实教育部学历学位认证(教育部存档!教育部留服网站永久可查)
四.办理各国各大学文凭(一对一专业服务,可全程监控跟踪进度)
如果您处于以下几种情况:
◇在校期间,因各种原因未能顺利毕业……拿不到官方毕业证【q/微741003700】
◇面对父母的压力,希望尽快拿到;
◇不清楚认证流程以及材料该如何准备;
◇回国时间很长,忘记办理;
◇回国马上就要找工作,办给用人单位看;
◇企事业单位必须要求办理的
◇需要报考公务员、购买免税车、落转户口
◇申请留学生创业基金
留信网认证的作用:
1:该专业认证可证明留学生真实身份
2:同时对留学生所学专业登记给予评定
3:国家专业人才认证中心颁发入库证书
4:这个认证书并且可以归档倒地方
5:凡事获得留信网入网的信息将会逐步更新到个人身份内,将在公安局网内查询个人身份证信息后,同步读取人才网入库信息
6:个人职称评审加20分
7:个人信誉贷款加10分
8:在国家人才网主办的国家网络招聘大会中纳入资料,供国家高端企业选择人才
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Applied Science: Thermodynamics, Laws & Methodology.pdf
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The binding of cosmological structures by massless topological defects
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Basics of crystallography, crystal systems, classes and different forms
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Immersive Learning That Works: Research Grounding and Paths Forward
Immersive Learning That Works: Research Grounding and Paths Forward
Describing and Interpreting an Immersive Learning Case with the Immersion Cub...
Describing and Interpreting an Immersive Learning Case with the Immersion Cub...
waterlessdyeingtechnolgyusing carbon dioxide chemicalspdf
waterlessdyeingtechnolgyusing carbon dioxide chemicalspdf
Authoring a personal GPT for your research and practice: How we created the Q...
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Physical quantities and their units
- 1. Length or Distance Time Mass Volume Density Velocity Acceleration Momentum Force Weight Pressure or Stress Energy or Work Kinetic Energy Potential Energy Power Impulse Action Angle Cycles Frequency Angular Velocity Angular Acceleration Moment of Inertia Angular Momentum Torque or Moment Temperature Heat Entropy Electric Charge +/− Current Voltage or Potential Resistance Capacitance Inductance Electric Field Electric Flux Magnetic Field Magnetic Flux fundamental fundamental fundamental distance3 Area distance2 mass / volume distance / time velocity / time mass × velocity mass × acceleration mass × acceleration of gravity force / area force × distance mass × velocity2 / 2 mass × acceleration of gravity × height energy / time force × time energy × time momentum × distance fundamental fundamental cycles / time angle / time angular velocity / time mass × radius2 radius × momentum moment of inertia radius × force moment of inertia fundamental heat energy heat / temperature fundamental charge / time energy / charge voltage / current charge / voltage voltage / (current / time) voltage / distance force / charge electric field × area force / (charge × velocity) magnetic field × area V = d3 A = d2 d = m/V v = d/t a = v/t p = m·v F = m·a W = m·g p = F/A E = F·d KE = m·v2/2 PE = m·g·h P = E/t I = F·t S = E·t S = p·d θ n f = n/t ω = θ/t α = ω/t I = m·r2 L = r·p L = I·ω τ = r·F τ = I·α T Q S = Q/T q i = q/t V = E/q R = V/i C = q/V L = V/(i/t) E = V/d E = F/q ΦE = E·A B = F/(q·v) ΦM = B·A m3 m2 kg/m3 m/s c (speed of light) m/s2 kg·m/s N (newton) = kg·m/s2 Pa (pascal) = N/m2 = kg/(m·s2) J (joule) = N·m = kg·m2/s2 W (watt) = J/s = kg·m2/s3 N·s = kg·m/s J·s = kg·m2/s ° (degree), rad (radian), rev 360° = 2π rad = 1 rev cyc (cycles) Hz (hertz) = cyc/s = 1/s rad/s = 1/s rad/s2 = 1/s2 kg·m2 J·s = kg·m2/s ħ (quantum of angular momentum) N·m = kg·m2/s2 °C (celsius), K (kelvin) J (joule) = kg·m2/s2 J/K C (coulomb) e (elementary charge) A (amp) = C/s V (volt) = J/C Ω (ohm) = V/A F (farad) = C/V H (henry) = V·s/A V/m = N/C V·m = N·m2/C T (tesla) = Wb/m2 = N·s/(C·m) Wb (weber) = V·s = J·s/C L3 L2 M/L3 L/T L/T2 ML/T ML/T2 M/LT2 ML2/T2 ML2/T3 ML/T ML2/T dimensionless dimensionless 1/T 1/T 1/T2 ML2 ML2/T ML2/T2 K (Temp.) ML2/T2 ML2/T2K Q (Charge) Q/T ML2/QT2 ML2/Q2T Q2T2/ML2 ML2/Q2 ML/QT2 ML3/QT2 M/QT ML2/QT d t m m (meter) s (second) kg (kilogram) L (Length) T (Time) M (Mass) × angular acceleration × angular velocity Mass, energy, momentum, angular momentum, and charge are conserved, which means the total amount does not change in an isolated system. Note: Other conventions define different quantities to be fundamental. h (quantum of action) Quantity Definition Formula Units Dimensions BasicMechanicalRotationalMechanicalThermalElectromagnetic Physical Quantities © 2003-2016 Keith Enevoldsen thinkzone.wlonk.com Creative Commons Attribution-ShareAlike 4.0 International License