| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 自然界中相互作用的五维空间模型的建立方法 | CN202111067086.6 | 2021-09-13 | CN113761750A | 2021-12-07 | 方东; 方舟; 商政; 孙思宇; 冯越 |
| 本发明公开了自然界中相互作用的五维空间模型的建立方法,基于标准模型和广义相对论的四大基本相互作用,以光能和/或热能为第五维的作用,在高能区、低能区分别产生了五大基本相互作用,对其分别建立五大基本相互作用的的数理模型。 | ||||||
| 2 | 制造任意时空曲率的装置的制造方法 | CN202310867873.1 | 2023-07-16 | CN117010175A | 2023-11-07 | 何世鸿 |
| 制造不同时空曲率的装置是根据广义相对论来命名的,如果从经典物理学来命名应当是制造不同强度引力的装置,制造方法是使用大量的激光器(注:或射线装置),让这些激光器发出的光束都指向同1个点或同1片区域,使得在“这1个点周围或这1片区域”形成特定能量密度的区域,根据广义相对论的原理在“这1个点周围或这1片区域”周围的时空会生成与“‘这1个点周围或这1片区域’的能量密度”相对应的“时空曲率”,或根据万有引力定律在“这1个点周围或这1片区域”产生与“‘这1个点周围或这1片区域’的能量密度”相对应的引力。 | ||||||
| 3 | 相对论量子计算机/量子引力计算机 | CN201980079510.3 | 2019-10-16 | CN113168585A | 2021-07-23 | 詹姆斯·塔格 |
| 经典计算机为了可靠地运行而抑制了量子不确定性,而量子计算机利用不确定性来提供附加的计算资源。经典计算机和量子计算机都在背景相依的确定性框架中运行,并以步进的方式处理信息。另一方面,量子引力计算机具有无限的因果结构,这是由广义相对论和量子力学之间的相互作用引起的,并且无法被建模为步进过程。该量子引力计算不以传统意义进行“计算”,但是仍根据规则来处理信息。这种计算机比步进式计算机具有更强大的能力,并且可应用于对其中量子力学和广义相对论都很重要的系统进行模拟,例如宇宙的早期阶段。它还可以作为人脑运作的模型,从而产生诸如理解力、自由意志力和创造力等的能力。 | ||||||
| 4 | 一种大尺度时空及在轨动态效应模拟方法 | CN201210592513.7 | 2012-12-29 | CN103047986A | 2013-04-17 | 贝晓敏; 帅平; 吴耀军; 徐立宏 |
| 本发明涉及一种大尺度时空及在轨动态效应模拟方法,在广义相对论框架下对构建大尺度时空基准进行定义后,建立空间基准和时间基准,从而实现同步;利用时空基准关系,将航天器接收到的光子脉冲时间转换到太阳系质心坐标系中,同预先设置的数据库中脉冲星计时模型预报的光子脉冲到达时间进行对比,获得航天器至太阳系质心的时间延迟量;利用信号调制器,调用数据库中的脉冲星特征参数数据和标准脉冲轮廓数据,生成电脉冲轮廓模拟信号,同时,并将得到的时间延迟量加载在信号中进行调制,输出到X射线信号发生器中,从而实现模拟。该方法能在有限空间、静态安置的地面试验验证系统中模拟在宇宙空间尺度和高动态环境下X射线光子信号传输效果。 | ||||||
| 5 | 复合框体 | CN201611271060.2 | 2016-12-23 | CN106676620A | 2017-05-17 | 刘智和 |
| 本发明任务是提出复合框体的制备方法。“新动力学”是本发明复合框体的基础理论。由五个定律构成的“新动力学”,是阐明微观粒子和宏观物体的力学规律和光速真相的新理论。我们推导的光线从恒星到地球的引力红移,比广义相对论的引力红移多一倍。它否定“宇宙大爆炸”。粒子的常数和函数的对称性,能够统一强力、电弱力和引力。至少有一维大尺度线条上所有的物粒本体距离都在纳米尺度内的物体,称为框体。由两种或两种以上性质不同的物质组合而成的一种多相框体,称为复合框体。采用扫描隧道显微镜,能按需要进行人工排布物粒,生成复合框体。 | ||||||
| 6 | 光线通过旋转透明介质改变轨迹 | CN201010292973.9 | 2011-01-03 | CN102013194A | 2011-04-13 | 刘武青 |
| 光线通过旋转透明介质改变轨迹发明目前是教学用具,现有的理论及观测等是:著名科学家爱因斯坦在广义相对论中预言,引力场会使光线偏转。英国的日全蚀观测队证实了这个预言。本发明目的是让光线通过透明介质,透明介质有静止、旋转两种状态,当光通过旋转透明介质与光通过静止介质比较,光的轨迹是不相同的。也就是讲,光线通过旋转透明介质,会使光线偏转。 | ||||||
| 7 | 车载时频重力位测量系统 | CN202410142379.3 | 2024-01-31 | CN117970512A | 2024-05-03 | 宁安; 申文斌 |
| 本发明涉及一种车载时频重力位测量系统,用于实时测量地球不同地点的重力位及重力场变化。该车辆配备了高精度原子钟、GNSS时频接收机、时频信号比对器、时间计数器、惯性导航系统(INS),可实时记录和分析地球重力位场及其微小变化。本发明以广义相对论为基础,利用重力频移法进行实时重力位测定。与传统方法相比,本发明具有如下优点:具有更大的数据观测量;具有更高的观测精度;可进行动态、实时重力位观测。 | ||||||
| 8 | 基于引力钟慢效应探测的全球重力场获取方法 | CN201910290437.6 | 2019-04-11 | CN110031906A | 2019-07-19 | 祝竺; 赵艳彬; 廖鹤; 刘梅林 |
| 本发明涉及一种基于引力钟慢效应探测的全球重力场获取方法,所述方法基于广义相对论原理,通过在卫星上搭载高精度原子光钟实现探测引力钟慢效应,进而获取全球重力场模型。本发明提出的测量方法有别于传统的基于牛顿力学的卫星重力测量方法,将先进的量子测量技术引入到大地测量中去,可获得较高的测量精度和稳定度,可应用于未来高分辨率的卫星重力测量任务。 | ||||||
| 9 | 一种天体引力场的测量装置及方法 | CN201910431587.4 | 2019-05-23 | CN110132127A | 2019-08-16 | 王志文 |
| 本发明公开了一种天体引力场的测量装置及其方法,包括两个相互垂直的光路,激光光源、分光镜、反光镜、光栅测量装置及垂直旋转装置,本发明利用广义相对论原理,通过光子在天体附近受引力作用使光线弯曲的引力透镜原理,把激光光源通过分光镜分为两束相互垂直的两路激光,经两个反射镜反射后在光栅测量装置处形成干涉条纹,通过旋转垂直旋转装置,使两个相互垂直的光路交替呈现水平或垂直状态,由相对论原理我们得出水平光路和垂直光路中运动的光子受引力影响的大小不同,使光子到达光栅测量装置处的时间随垂直旋转装置周期变化,造成光栅测量装置处干涉条纹的周期移动,计算移动光栅的相位差即可算出该处引力场的大小。 | ||||||
| 10 | 萨洛蒙“死谷”(Dead Valley)的测试方法 | CN201710144021.4 | 2017-03-01 | CN108067941A | 2018-05-25 | 刘沛恩 |
| 萨洛蒙“死谷”(eadValley)的测试方法表明,超高速切削科学定义是:剪切区产生“长度收缩”和“时间膨胀”效果的切削速度的切削。将其引伸,我们认为所有系的物质能量都是平衡的,因其平衡的条件不同,相对失去能量平衡的物质称做暗物质。其特点:暗物质存在一条“通过引入一个引力场,我们可以把一个加速系视为伽利略系。”的时空隧道,能够把失去平衡的能量加速到更高速度的能量平衡。萨洛蒙将失去能量平衡的剪切区称为“死谷”,他所提出的“由于切削温度太高(高于刀具材料允许的最高温度to),任何刀具都无法承受,切削加工不可能进行。”的现象是一个假象。沃汉的实验结果帮助我们找出萨洛蒙理论的错误之处。本发明解释了“死谷”剪切区的切削机理效果与超高速切削的效果等同。验证了爱因斯坦广义相对论与实践处处吻合。 | ||||||
| 11 | 一种多重多维动力系统运动模型构建与模拟方法 | CN202011061206.7 | 2020-09-30 | CN112185471A | 2021-01-05 | 阳国新 |
| 本发明公开了一种多重多维动力系统运动模型构建与模拟方法,通过对提出多重多维动力系统运动模型进行构建与模拟,利用将每重动力系统中运动因子的运动轨迹嵌套代入下一重动力子系统建立其动力子系统运动因子的运动轨迹,直至获得最小动力子系统中运动因子的动力轨迹模型进行多重多维动力系统运动模型构建。旨在解决现有技术中存在的多重动力系统模型的构建只适用于简单模型构建,同时构建运动模型不能对微观量子效应和宏观宇宙广义相对论进行共同的解释的技术问题。基于上述构建与模拟的多重多维动力系统能够统一微观粒子与宏观宇宙中所有的运动因子的运动规律。对量子理论、时空弯曲及高维时空、多重宇宙、粒子物理模型、超弦理论进行合理解释。 | ||||||
| 12 | 一种大尺度时空及在轨动态效应模拟方法 | CN201210592513.7 | 2012-12-29 | CN103047986B | 2016-08-10 | 贝晓敏; 帅平; 吴耀军; 徐立宏 |
| 本发明涉及一种大尺度时空及在轨动态效应模拟方法,在广义相对论框架下对构建大尺度时空基准进行定义后,建立空间基准和时间基准,从而实现同步;利用时空基准关系,将航天器接收到的光子脉冲时间转换到太阳系质心坐标系中,同预先设置的数据库中脉冲星计时模型预报的光子脉冲到达时间进行对比,获得航天器至太阳系质心的时间延迟量;利用信号调制器,调用数据库中的脉冲星特征参数数据和标准脉冲轮廓数据,生成电脉冲轮廓模拟信号,同时,并将得到的时间延迟量加载在信号中进行调制,输出到X射线信号发生器中,从而实现模拟。该方法能在有限空间、静态安置的地面试验验证系统中模拟在宇宙空间尺度和高动态环境下X射线光子信号传输效果。 | ||||||
| 13 | 微重力实验仪 | CN98229113.2 | 1998-07-15 | CN2334067Y | 1999-08-18 | 李俊伦 |
| 一种微重实验仪,属于物理教学实验仪器。该仪器利用爱因斯坦广义相对论的等效原理能观测记录落体室作无自转自由下落时,室体中物体在接近于不受外力作用下的局部惯性系中的物性与运动规律,它包括升降机1、导轨6、电缆2、释放器3、落体室5、落体室导环4和减振器7,其特征是释放器上固定有轴心相叠、轴心连线在水平上的两磁环,两磁环具有相同的磁场方向;落体室上也固定有一磁环,当落体室挂在释放器的电磁挂钩上时,落体室上的磁环正好置于释放器两磁环之间,其磁场方向与释放器器两磁环磁场方向相反,三磁环形成一防转器8。 | ||||||
| 14 | METHOD OF CONTROLLING GRAVITATIONAL ACCELERATION | PCT/JP1978000030 | 1978-11-18 | WO1980001114A1 | 1980-05-29 | |
| This invention is performed on the basis of the recognition on physics, that repulsion accelerating substances of approximately 10 |
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| 15 | Technical and theoretical specifications for warp drive technology | US10182373 | 2002-10-25 | US20030114313A1 | 2003-06-19 | Andrew Peter Worsley; Peter John Twist |
| The present invention relates to the use of technical drive systems, which operate by the modification of gravitational fields. These drive systems do not depend on the emission of matter to create thrust but create a change in the curvature of space-time, in accordance with general relativity. This allows travel by warping space-time to produce an independent warp drive system. Differentials electron flow through a body in rotation is directed so as to simultaneously pass through a said body In its direction of | ||||||
| 16 | TECHNICAL AND THEORETICAL SPECIFICATIONS FOR WARP DRIVE TECHNOLOGY | PCT/GB2001/000381 | 2001-01-30 | WO01057881A1 | 2001-08-09 | |
| The present invention relates to the use of technical drive systems, which operate by the modification of gravitational fields. These drive systems do not depend on the emission of matter to create thrust but create a change in the curvature of space-time, in accordance with general relativity. This allows travel by warping space-time to produce an independent warp drive system. Differential electron flow through a body in rotation is directed so as to simultaneously pass through a said body in its direction of rotation and contrary to its direction of rotation so as to release a directed flow of gravitons. | ||||||
| 17 | Static/dynamic control for optimizing a useful objective | US09276619 | 1999-03-25 | US06496741B1 | 2002-12-17 | Gregory J. Whiffen |
| A method, computer system, and program product for optimizing a useful objective function with respect to a dynamic parameter vector and a static parameter vector. The method, called the static/dynamic control (MDC) method, either minimizes or maximizes the useful objective function subject to a state equation, initial conditions, terminal conditions, constraints, and dynamic limitations. The SDC method includes an algorithm having two formulations: a period formulation and a fully continuous formulation. With the period formulation, the dynamic optimization variables associated with the dynamic limitations are permitted to be discontinuous, parametric functions of time. With the fully continuous formulation, the dynamic optimization variables are permitted to be continuous, non-parametric functions of time. The SDC method is computer implementable and employs an iterative process including an inner loop and an outer loop. The inner loop terminates when the objective function has changed by a satisfactory amount during a fixed outer-loop iteration. The outer loop terminates when the SDC procedure converges. The SDC method may be used to optimize a spacecraft trajectory objective and a spacecraft design objective simultaneously. Optimizing spacecraft objectives via SDC does not require approximating the physics or dynamics of space flight. Thus, any number of gravitating bodies, gravitational harmonics, radiation pressure, atmospheric drag, and general relativistic corrections can be accounted for when using the SDC method. The SDC method does not require prespecification of a planetary flyby sequence for space flight and is capable of identifying optimal flyby sequences. | ||||||
| 18 | APPARATUS AND METHOD FOR PROVIDING AN ANTIGRAVITATIONAL FORCE | PCT/US1990003441 | 1990-06-14 | WO1990016073A1 | 1990-12-27 | |
| A method and means for providing antigravitational force comprising means for providing a source of matter having a spacetime curvature opposite that of a gravitating body where opposite curvatures provide mutually repulsive antigravitational force, and method and means for applying a force on the oppositely curved matter from the source wherein in the case of the Earth, the resulting force balance provides repulsive gravitational work on the oppositely curved matter and the gravitational field of the gravitating body in the first positive curvature of spacetime. The opposite, or negative curvature of matter is provided according to a two-dimensional manifold of negative curvature derived on a novel atomic theory which is consistent with Newtonian mechanics, Maxwell's equations, atomic theory, General Relativity and the weak and strong nuclear forces and which permits the calculation of any matter, energy, or force in terms of fundamental constants of nature. According to the present invention the spacetime manifold of negative curvature is a solution of the equations and boundary conditions of the novel atomic theory comprising, in part a three-dimensional wave equation. The manifold satisfies the boundary condition that its spacetime Fourier transform contains no components which are synchronous with waves traveling at the speed of light; therefore, the manifold is non-radiative. In one embodiment, the matter of negative curvature provided by the source moves at a constant velocity at force balance to produce useful work against the gravitational field of the gravitating body to provide apparatus useful to produce levitation and propulsion. In one embodiment, electromagnetic force is converted to gravitational force and subsequently converted to a mechanical force which provides the useful propulsion or levitation. In alternative embodiments, the electromagnetic force is provided by a generator driven by steam, for example, where the energy of the strong nuclear force provides the heat energy to provide the steam. Alternatively, the heat energy is converted directly to the electromagnetic force via a generator such as a thermionic generator. | ||||||
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