REVIEW OF GRAVITATIONAL WAVE DETECTIONS: DYNAMICAL SPACE

Reginald Thomas Cahill

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REVIEW OF GRAVITATIONAL WAVE DETECTIONS: DYNAMICAL SPACE

机译：重力波检测综述：动态空间

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This is a review of the numerous successful gravitational wave detections and the implications for the nature of space and time. The prevailing space time paradigm in physics was founded on the putative "null" results of the Michelson-Morley (MM) 1887 interferometer experiment to detect light speed anisotropy and which resulted in two different new relativity theories: Lorentz relativity (Lorentz, 1904) and special relativity (Einstein, 1905),with the later invoking the claimed reality of space time, in place of separate phenomena of space and time. Miller (1933) repeated the MM experiment in 1925/26 and obtained non-null quality data, resulting in the determination of light speed anisotropy and establishing the key sidereal effect. It is now understood, since 2002,that both of these experiments are consistent and that the MM 1887 experiment was never null: Michelson had used Newtonian physics to calibrate the interferometer. Using Lorentz Relativity, but not Special Relativity, it is now possible to analyse the data from these experiments and which shows that the Michelson interferometer has zero sensitivity unless operated with a dielectric present in the light paths; air in the MM1887 and Miller experiments. Since that 2002 analysis various older and new light speed anisotropy experiments have produced fully consistent results, using different experimental techniques. These have included: RF EM Speeds in coaxial cable, optical fiber Michelson Interferometer, optical fiber/RF coaxial cables, earth spacecraft flyby RF doppler shifts, 1st order dual RF coaxial cables. These are all classical phenomena detectors. However in 2013 nanotechnology quantum detectors were invented that use correlations between electron barrier tunnelling current fluctuations in spatially separated zener diodes. Not only do all of these experiments, spanning 125 years, give a consistent anisotropy velocity, with speed -500 km/s, RA -5 h,Dec. ~80deg S,but all showed significant fluctuations in that velocity. A neo-lorentzian interpretation of these results is that a dynamical 3-space is passing the solar system and exhibits turbulence/wave effects. These wave effects produce gravitational forces and so the experimental data implies that the Michelson and Morley experiment not only detected light speed anisotropy but detected "gravitational waves". These gravitational waves have properties that are not consistent with the general relativity predicted waves, which travel at the speed of light, are transverse polarised and are weak and only produced by distant major astronomical events. Gravitational waves with these properties have never been detected. The zener diode quantum detectors reveal that quantum fluctuations are not random and intrinsic to a quantum system, but are imposed by the passing space: This discovery has major implications for the interpretations of quantum theory and the quantum to classical transition, which profoundly creates our reality. The dynamical space theory also posses an intrinsic inflation epoch.

机译：这是对众多成功的引力波检测及其对时空性质的影响的综述。物理学中流行的时空范式是建立在1887年的迈克尔逊·莫雷（MM）干涉仪实验的假定“零”结果基础上的，该实验用于检测光速各向异性，并产生了两种不同的新的相对论：洛伦兹相对论（Lorentz，1904年）和狭义相对论（爱因斯坦，1905年），后来又引用了所谓的时空现实，代替了时空的分离现象。 Miller（1933）在1925/26中重复进行MM实验，获得了非零质量数据，从而确定了光速各向异性并确定了关键的恒星效应。自2002年以来，我们已经知道这两个实验是一致的，并且MM 1887实验永远不会失败：迈克尔逊使用牛顿物理学来校准干涉仪。使用洛伦兹相对论而不是狭义相对论，现在有可能分析这些实验的数据，这表明迈克尔逊干涉仪除非在光路中存在电介质，否则灵敏度为零。在MM1887和Miller实验中进行空气测试。自2002年以来，使用不同的实验技术，各种旧的和新的光速各向异性实验都产生了完全一致的结果。其中包括：同轴电缆中的RF EM速度，光纤迈克尔逊干涉仪，光纤/ RF同轴电缆，地球飞船飞越RF多普勒频移，一阶双RF同轴电缆。这些都是经典现象检测器。然而，在2013年，发明了纳米技术量子探测器，该探测器利用空间分隔的齐纳二极管中电子势垒隧穿电流波动之间的相关性。所有这些跨越125年的实验不仅给出了一致的各向异性速度，速度为-500 km / s，RA -5 h，12月。〜80deg S，但所有速度都显示出明显的波动。对这些结果的新劳伦兹式解释是，动态的3空间正在通过太阳系，并表现出湍流/波效应。这些波效应会产生重力，因此实验数据表明，迈克尔逊和莫利实验不仅检测到光速各向异性，而且检测到“引力波”。这些引力波具有与广义相对论预测波不一致的特性，后者以光速传播，被横向极化并且是微弱的并且仅由遥远的主要天文事件产生。具有这些性质的引力波从未被检测到。齐纳二极管量子探测器揭示了量子涨落不是随机的，并且是量子系统固有的，而是由经过的空间施加的：这一发现对量子理论的解释以及从量子到经典跃迁具有重大意义，深刻地创造了我们的现实。动力学空间理论还提出了一个固有的通货膨胀时代。

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《Physics International》 |2014年第1期|共38页
作者
Reginald Thomas Cahill;
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正文语种 eng
中图分类物理学;
关键词
Gravitational Waves; Light Speed Anisotropy; Dynamical 3-Space; Quantum Classical Transition;

机译：引力波光速各向异性动态三空间量子经典跃迁;

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专利

1. REVIEW OF GRAVITATIONAL WAVE DETECTIONS: DYNAMICAL SPACE [J] . Reginald Thomas Cahill Physics International . 2014,第1期

机译：重力波检测综述：动态空间
2. Dynamical 3-Space: Gravitational Wave Detection and the Shnoll Effect [J] . David P. Rothall, Reginald T. Cahill Progress in Physics . 2013,第4期

机译：动力学3空间：引力波检测和Shnoll效应
3. Gravitational Wave (GW) Classification, Space GW Detection Sensitivities and AMIGO (Astrodynamical Middle-frequency Interferometric GW Observatory) [J] . Wei-Tou Ni EPJ Web of Conferences . 2018,第12期

机译：引力波（GW）的分类，空间GW的探测灵敏度和AMIGO（天文学中频干涉式GW天文台）
4. Dynamic Matched Filter for the Detection of Gravitational Waves [C] . Fausto Acernese, Fabrizio Barone, Rosario De Rosa, Conference on Gravitational Wave and Particle Astrophysics Detectors; 20040623-20040624; Glasgow; GB . 2004

机译：动态匹配滤波器检测引力波
5. Constraining the r-mode saturation amplitude from a hypothetical detection of r-mode gravitational waves from a newborn neutron star: Detection strategies and machine learning algorithms. [D] . Mitidis, Andonis. 2015

机译：通过假设检测来自新生中子星的r模式引力波来约束r模式饱和幅度：检测策略和机器学习算法。
6. Gravitational Wave Detection by Interferometry (Ground and Space) [O] . Matthew Pitkin, Stuart Reid, Sheila Rowan, -1

机译：干涉法重力波检测（地面和空间）
7. Dynamical 3-Space: Gravitational Wave Detection and the Shnoll Effect [O] . Rothall D. P., Cahill R. T. 2013

机译：动态三维空间：引力波探测和shnoll效应

REVIEW OF GRAVITATIONAL WAVE DETECTIONS: DYNAMICAL SPACE

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