Measuring human in vivo gravitational waves and the origin of an elastic reference memory

AbstractThese data were generated to investigate gravitational binding inversion energy impacts on objects' FHD (falling height difference) at free fall state, ranging from close to rigid body objects, and liquids, to organisms including human beings.Historically, it is believed that the masses of free fall objects are independent of their weight measuring; however, we find such independence will be impacted by the internal motion of falling objects greatly, we then design the FHD indicator with board application and theoretical significance for bio-systems.In the falling height difference measurement, we first compare the FHD of slinky objects with internal motion and those objects without internal motion to find the source of FHD. Then test the FHDs of half bottle of oil and a half bottle of water, use liquid nitrogen treatment as CK to confirm that the FHDs come from internal motion.To test the FHDs of organisms, we compare the dead and alive states of organisms, also use liquid nitrogen treated alive organism to confirm that the FHDs of alive state come from internal motion.Finally, we test the human FHDs from a 10m diving platform, and also test the FHDs of animals before and after sexual behavior; and the FHDs of plant raw seeds and germinated seeds from the same batch.These experiments clearly reveal the origin of elastic reference systems and memory. Free-fall of rigid bodies following the conservation of common energy can issue legendary Galileo results. Free-fall of elastic objects such as half bottle of water begin to show elastic reference characteristics. We can section such free-fall height h into stages as h1 to hk, then for each stage hi inversion energy begins to accumulate in a small amount, common energy conservation is then impacted by the inversion energy E1 to k , thus inducing FHDs between a water bottle/oil bottle pair. To bio-systems, the little fraction of inversion energy E1 to k impacts are enlarged greatly, then all bio-systems follow inversion energy conservation instead of common energy conservation. To conserve inversion energy, bio-systems only take inversion (energy) induced by parameters instead of direct parameter data, not only in free-fall steps but also in all functional stages. It seems bio-systems internal interactions, such as from genomics to proteomics, to cells, tissues, and to organs, etc., or external interactions, such as eating, migrations, diverse activities, etc., are much more diverse and complicated; however, they indeed all belong to elastic reference systems and are as simple as the free-fall of liquid bottles in the experiments, nothing more than each step hi only takes inversion energy E1 to Ek induced by parameters instead of parameters themselves and then equivalents with memorized patterns, albeit the inversion energy of free-fall liquids are much lower than those in alive bio-systems. (It is noted that universal memory is not only present in living systems, but any non-living beings like our free-fall bottle liquids also possess such primitive “memory” albeit the level is quite lower, the resulting FHDs are from such universal “memory”) Our methods reveal the elastic reference memory quite well. Modifications of Newtonian three Laws also come from these designs. Usage NotesThis dataset originates modification of Newtonian Three Laws of Motion for bio-systems, it is recommended to design new equivalent experiments from these modification laws. The samples measured in this paper are only a very small fraction of all species on Earth, there are still a lot of samples waiting to be tested for theoretical studies as well as applications. Also, the lifetime standard curve will be more significant than a point test; therefore, it is strongly recommended to test the human lifetime FHD standard curve. As suggested in the paper, it could start from around 6 years old till the final 5 years. Such a lifetime FHD standard curve can’t be replaced by any other test. Even for animals and plant samples, the lifetime FHD standard curve is still critical. We can know more about the gravitational quiddity of ourselves and the whole biological kingdom by such kind of lifetime standard curves. (Due to the COVID-19 pandemic and other reasons, this paper still does not get a lifetime FHD standard curve. However, scholars and the global public should try lifetime FHD standard curves or support such study.)Dateset descriptionThis readme file was generated on [2020-06-01] by [Yi Yu Lai] GENERAL INFORMATIONTitle of Dataset: Measuring human in vivo gravitational waves and the origin of an elastic reference memoryAuthor/Principal Investigator InformationName: Yi Yu LaiORCID: 0000-0002-0113-8795Institution: Innoen Gravitational InstituteAddress: 6-61 Ardglen Dr. Brampton, L6W1V1, Ontario, Canada(office) The experiments need field tests, various locations on Great Toronto region & Guizhou Province in China (Test sites)Email: yylai@innoen.org Date of data collection: From 2019-12-23 to 2020-4-25, human diving on 10m platform data were collected on 2020-2-15 in Canada Ontario Etobicoke diving club.Various locations in the Great Toronto area in Canada and Guizhou Province in China for various experiments in the paper (Guizhou locations performed mutation 1.4: two bi-layer metal balls free-fall experiment for 6 repetitions and mutation 1.5 for around 100 tests with different bottle sizes and oil types, location around 26.423532, 106.674131, no liquid nitrogen mutation performed in this location.) The videos in the paper were performed at Mississauga, Canada: 43.62942, -79.66731, including liquid nitrogen mutations, also various other experimental locations in the GTA area and Ontario. The human diving data were collected at Etobicoke Olympium, address: 590 Rathburn Rd, Etobicoke, ON M9C 3T3 , Canada (43.65048, -79.58436) Information about funding sources that supported the collection of the data: No funding SHARING/ACCESS INFORMATION Licenses/restrictions placed on the data:Performing similar experiments need to comply with relevant ethical requirements, E.g., vertebrate animals need ethical approval, in this paper, human diving is a sportive activity to understand in vivo gravitational waves, only needs licensed diving coaches to assure the diving safety since no somatic body intervention or biological sample was taken out. However, if future designs involve intervention or somatic samples during the diving activities, then need additional clinical trial compliance. Links to publications that cite or use the data: Lai, Y.Y. Measuring the “Weight” of Human in vivo Bio-Inertia by Legendary Galileo Falling Body Experiments on a Commercial 10m Diving Platform and Gravitationally Inversion of Newton's Three Laws of Motion into the Basic Laws of Evolution. IJSR, 10(9), 1301-1328 (2021). (http://doi.org/10.21275/SR21829103822) Was data derived from another source?If yes, list source(s): No Recommended citation for this dataset: DOI: 10.57760/sciencedb.02448DATA & FILE OVERVIEWFile List:Tab 3: A half bottle of water VS a half bottle of oil liquid nitrogen mutation free-fall experiments. Tab 4: Different animals/plant alive samples VS their dead counterparts for free-fall experiments.Tab 5: Raw mung bean seeds and soybean seeds VS germination state for free-fall experiments.Tab 6: liquid nitrogen mutation of Tab 4.Tab 7: Human free-fall from a commercial 10m diving platform against a metal bar experimentsTab 8: Animal before sexual behavior and after sexual behavior free-fall experimentsSupplementary Movie 1. part of the Apollo 15 experiment video on the Moon (1971 by astronaut David Scott)Supplementary Movie 2. the movement of a free suspension slinky after releaseSupplementary Movie 3. the FHD of a metal chain and a same-length slinky from 7.05mSupplementary Movie 4. the FHD of a half-bottle of oil and a half bottle of water from 7.04m_video by a 6-year-old kindergarten girl from Dorset Public School, Brampton, CanadaSupplementary Movie 5. bio quantum path experiment for the definition of bio-inertiaSupplementary Movie 6. the FHD of a dead(cooked) apple and an alive apple from 7.04m_video by a 6-year-old kindergarten girl from Dorset Public SchoolSupplementary Movie 7. the FHD of a rat and a metal weight from 7.04mSupplementary Movie 8.the FDH of soybean seeds after soaking 24H against raw seeds from 7.04mSupplementary Movie 9. accepted diving posture 1Supplementary Movie 10. accepted diving posture 2Supplementary Movie 11. ancient training for increasing the surface tension of spinal vertebrae METHODOLOGICAL INFORMATIONDescription of methods used for collection/generation of data:From linked paper, refer to the Experimental section: (http://doi.org/10.21275/SR21829103822) Methods for processing the data: Directly use a video camera to get the FHDs, manually collect as written in the paper. Instrument- or software-specific information needed to interpret the data: Video camera, rack, metal bar, laser distance meter, ice-cream clips, safety rope, liquid nitrogen jar, and other accessories. Standards and calibration information, if appropriate: The laser distance meter follows the manufacturer’s calibration. Plant samples need to fix on the rack for 5 mins to be stable, also choose windless conditions. For liquid nitrogen overnight mutation, we choose 20 seconds of stabilizing time instead of the normal 5 mins stabilizing time. For animal testing, try to avoid extra body motion in the free-fall, such as tying the wings, etc. Be careful, the impact of sexual behavior on the FHDs can't be neglected, try to avoid such impacts for at least one week. For humans close to free-fall state from the 10m platform, only two diving styles as in supplementary movie 9 and movie 10 are allowed. However, these two postures are still not the ideal condition, in the paper, we suggested a horizontal bar holding posture for FHD testing, that way can get reliable results. Environmental/experimental conditions: Avoid the impacts of wind or airflow, give enough stabilizing time and also refer to the above Standards and calibration information. And the experiments in the paper are only preliminary experiments to assure FHDs are 100% present, still have a long way to go to attain the lifetime FHD standard curves that can offer substantial information. Describe any quality-assurance procedures performed on the data: For all the experiments, try to repeat experiments on the same day and under the same condition, and also repeat on a different day in the same location. Only enough reproducible results are used. For human diving from the 10m platform, we only get one opportunity to test, therefore, no different day results for comparison. It is still highly recommended the lifetime FHD standard curve for reflecting the bio-inertia. People involved with sample collection, processing, analysis and/or submission: Yi Yu Lai, Jingli Xing, Rong Yong Weng, Guangxin Lai. DATA-SPECIFIC INFORMATION FOR: [Tab. 3]Number of variables: 4 Number of cases/rows: 6 Variable List: <bottle size: 330ml, 500ml; liquid nitrogen: treat overnight, untreated bottle contents: water, commercial plant oil; falling height: 5.28m, 7.04m, 23.56mMissing data codes: <NA> Specialized formats or other abbreviations used: NATab 3: the unit of FHD in this paper is cm.Pre-experiments that generate the following liquid nitrogen mutation experiments:A half bottle of water and a half bottle of oil visually prepared were composed of a trial pair, released from a height, and a video camera was used to calculate the FHDs (falling height difference). In total 600 pairs (1200 bottles) with different parameters in different countries, all with falling heights larger than 20cm, all resulted in the oil bottles hitting the ground first. Measuring one experimental pair, the oil bottle is 173.274g, and the water bottle measured 184.125g, due to the density difference, all the test pairs should be the oil bottle is lighter than the water bottle, and the lighter bottle hits the ground first. The parameters refer in these 600 tests are: height from 4.82 to 23.65m; bottle size 330ml, 500ml, and 750ml; oil type: canola oil, vegetable oil, sunflower oil, peanut oil, soybean oil, car engine oil. Location: Ontario Canada, Guizhou Province of China.Formal liquid nitrogen mutation experiments:24 commercial drinking water bottles (12 × 330ml, 12× 500ml) compose of 12 experimental pairs (a half bottle of plant oil and a half bottle of water of the same height), 6 pairs treated with liquid nitrogen overnight and six not, released from the heights of 5.28 m, 7.04m, and 23.65m; FHDs present in (Tab.3), the stabilizing time for normal pairs is 5 mins and for liquid nitrogen treated pairs is 20s. For the six experimental pairs without liquid nitrogen treatment present FHDs in the table and the oil bottle hits the ground first; however, for the six experimental pairs after liquid nitrogen overnight, water bottles and oil bottles hit the ground simultaneously. This result demonstrates the internal motion of the bottle liquid contents plays a critical role in FHDs. DATA-SPECIFIC INFORMATION FOR: [Tab. 4]Number of variables: 3 Number of cases/rows: 34 Variable List: < species: 34; living state: dead or alive (sometimes metal bar replace dead samples); repetition: 3 samples each species; falling height: 7.04m Missing data codes: <NA> Specialized formats or other abbreviations used: spl, means each species take 3 repetitions. Tab 4: Different alive animals and plant samples VS their dead counterparts or a metal bar to demonstrate significant FHDs between them, three repetitions, validated different gravitational binding between the alive and the dead state of bio-systems (the advantage of this design over mutations of Cavendish experiments is that it can acquire in vivo gravitational waves or bio-inertia. It is this design that generates the method for testing human in vivo gravitational waves or bio-inertia and establishes the theoretical foundation of the paper.) DATA-SPECIFIC INFORMATION FOR: [Tab. 5]Number of variables: 2 Number of cases/rows: 4 Variable List: < seeds: mung beans, soybeans; germination: 24H, 48H> ; falling height: 7.04m Missing data codes: <NA> Specialized formats or other abbreviations used: spl means each sample takes three repetitions. Tab 5: Raw mung bean seeds and soybean seeds, soaked in water for 24 hours and 48 hours, put inside centrifuge bottles, and released from a height. The raw seeds hit the ground first, which means the seed's germination process accumulates more gravitational binding than raw seeds and is sensitive to our FHD tests. DATA-SPECIFIC INFORMATION FOR: [Tab. 6]Number of variables: 2 Number of cases/rows: 10Variable List: <falling height: 5.48m, 7.54m; species: apples, pears, tomatoes, lobsters, mice>Missing data codes: <NA> Specialized formats or other abbreviations used: < NA> Tab 6: Tab 4 has demonstrated that FHDs are present between the dead and alive state of a living being. We used some experimental pairs from Tab 4 and fixed them with liquid nitrogen overnight, then the FHDs present in Tab 4 recovered back to 0 again, this confirms for living beings, the FHDs do originate from internal motion. DATA-SPECIFIC INFORMATION FOR: [Tab. 7]Number of variables: 1 Number of cases/rows: 8 Variable List: < falling height: 10m, eight volunteers, only permit two compromised diving styles> Missing data codes: <no missing data, however, the idea diving style should use a horizontal bar rack, we lack it, and have to compromise to two inferior styles>Specialized formats or other abbreviations used: < NA> Tab 7: Human diving from a commercial 10m diving platform against a metal bar, demonstrating significant FHDs. This experiment combined with previous experiments suggests that FHD testing is a reliable method for testing bio-inertia or integrating health conditions. It is highly recommended to use a lifetime FHD standard curve for health monitor and evaluation. DATA-SPECIFIC INFORMATION FOR: [Tab. 8]Number of variables: 1 Number of cases/rows: 5Variable List: < animals: 3 three one-year roosters and 2 one-year male rabbits. falling height: roosters, 5.28m, rabbits, 5.44m, behavior: before and after sexual behavior >Missing data codes: < NA> Specialized formats or other abbreviations used: < spl means three repetitions of FHDs before sexual behavior, after sexual behavior, only test one repetition of FHD for calculating loss> Tab 8: One-year visually healthy male animals were selected and separated from female partners for one month, then free-fall into a trampoline three times to average into FHDs before sex. After sexual behavior then tests the FHDs again to calculate the FHD sexual loss. After sexual behavior all animals show significant FHD, corresponding to the ancient Kungfu experience that sexual behavior will lose significant gravitational binding or bio-inertia for men (following ancient physical training experiences, after sexual behavior, male animals lose gravitational binding substantially and female animals should acquire part of the gravitational binding. In Wudang system, there are strict sexual restrictions for men; however, almost no restrictions for women. Using our FHD test can easily get sexual behavior gravitational binding loss for male animals; however, it is not easy to get the sexual behavior gravitational binding acquirement for female animals. Possibly it still needs some technological improvement for testing the female gravitational binding accumulation conditions).

**摘要** 本数据集旨在探究引力结合反演能对自由落体状态下物体下落高度差（falling height difference, FHD）的影响，实验对象涵盖近刚体物体、液态物质乃至包括人类在内的生物。 长期以来，学界普遍认为自由落体物体的质量与其重量测量无关；但本研究发现，该无关性会受落体内部运动的显著影响。据此，我们设计了具有广泛应用价值与理论意义的生物系统FHD表征指标。 在下落高度差测量实验中，我们首先对比了存在内部运动的软弹簧（slinky）物体与无内部运动物体的FHD，以探明FHD的来源；随后测试了半瓶油与半瓶水的FHD，并以液氮处理作为对照（CK），证实FHD源于物体内部运动。 为测试生物的FHD，我们对比了生物的死亡与存活状态，并通过液氮处理后的存活生物样本，证实存活状态下的FHD同样源于内部运动。 最后，我们测试了人类在10米跳台的FHD，同时检测了动物性行为前后的FHD，以及同一批次植物原始种子与萌发种子的FHD。 上述实验清晰揭示了弹性参考系与记忆的起源。遵循常规能量守恒的刚体自由落体可得到经典的伽利略落体结果；而半瓶水这类弹性物体的自由落体则开始表现出弹性参考系特性。 我们可将自由落体高度h划分为h₁至hₖ若干阶段，每个阶段hᵢ中反演能开始少量积累，常规能量守恒会受E₁至Eₖ反演能的影响，进而引发水瓶/油瓶组间的FHD。 对于生物系统而言，E₁至Eₖ反演能的微弱影响会被大幅放大，因此所有生物系统遵循反演能守恒而非常规能量守恒。为维持反演能守恒，生物系统仅会提取由参数诱导产生的反演（能）而非直接使用参数数据，这一规律不仅存在于自由落体阶段，也适用于所有功能活动阶段。 尽管生物系统的内部相互作用（如从基因组学到蛋白质组学，再到细胞、组织与器官等层级）与外部相互作用（如进食、迁徙、各类活动等）更为复杂多样，但它们本质上均属于弹性参考系，其原理与实验中液态瓶体的自由落体并无二致：每个阶段hᵢ仅提取由参数诱导产生的反演能E₁至Eₖ而非参数本身，进而等价于记忆模式。只不过自由落体液态物质的反演能远低于存活生物系统。 （需说明的是，普适性记忆不仅存在于生命系统，诸如自由落体瓶内液体等非生命物质同样具备此类原始“记忆”，尽管其水平极低，而观测到的FHD正是源于这种普适性“记忆”。）我们的方法很好地揭示了弹性参考系记忆的本质，而对牛顿三大定律的修正正是源自上述实验设计。 **使用说明** 本数据集源于针对生物系统的牛顿三大运动定律修正研究，建议基于这些修正定律设计等效的新实验。本研究中实测的样本仅为地球所有物种的极小一部分，仍有大量样本有待开展理论研究与应用测试。此外，生命周期标准曲线相较于单点测试更具价值，因此强烈建议构建人类全生命周期FHD标准曲线。如论文所述，该曲线的测试可从约6岁开始，直至生命最后5年。此类全生命周期FHD标准曲线无法被任何其他测试所替代。即便对于动物与植物样本，全生命周期FHD标准曲线同样至关重要。通过这类生命周期标准曲线，我们可更深入地理解人类自身乃至整个生物界的引力本质。（受COVID-19疫情等因素影响，本研究尚未获得全生命周期FHD标准曲线，但恳请学界与全球公众尝试开展或支持此类研究。） ## 数据集基本信息 **数据集标题** 人体体内引力波测量与弹性参考系记忆的起源 **负责人/主要研究者信息** 姓名：赖亦宇 ORCID：0000-0002-0113-8795 所属机构：Innoen引力研究所 办公地址：加拿大安大略省宾顿市阿德格伦大道6-61号，邮编L6W1V1 实验测试地点：加拿大大多伦多地区与中国贵州省多地 电子邮箱：yylai@innoen.org **数据采集时间** 2019年12月23日至2020年4月25日；其中人类10米跳台跳水数据采集于2020年2月15日，地点为加拿大安大略省伊托比科跳水俱乐部。本研究的各类实验分别在加拿大大多伦多地区与中国贵州省多地开展（贵州省测试点坐标约为26.423532, 106.674131，该地点完成了1.4号变体实验：双层金属球自由落体实验6次重复，以及1.5号变体实验：针对不同瓶型与油品的约100组测试，未开展液氮变体实验）。论文中的视频拍摄于加拿大密西沙加市（坐标43.62942, -79.66731），涵盖液氮变体实验，同时也在GTA地区与安大略省的其他多个地点开展了实验。人类跳水数据采集于伊托比科奥林匹亚体育中心，地址：加拿大安大略省伊托比克拉思伯恩路590号，邮编M9C 3T3（坐标43.65048, -79.58436）。 **资助信息** 本数据采集未获得任何资助。 ## 共享与使用信息 **使用许可与限制** 开展类似实验需遵守相关伦理规范，例如脊椎动物实验需获得伦理审批。本研究中的人类跳水活动为用于探究体内引力波的体育项目，未涉及身体干预或生物样本采集，仅需持有资质的跳水教练保障跳水安全。但若未来的实验设计涉及跳水过程中的身体干预或生物样本采集，则需额外符合临床试验规范。 **关联引用文献** Lai, Y.Y. 通过商用10米跳台的经典伽利略落体实验测量人体体内生物惯性的“重量”，以及将牛顿三大运动定律引力反演为进化基本定律. 国际科学研究杂志(IJSR), 10(9), 1301-1328 (2021). (http://doi.org/10.21275/SR21829103822) **数据来源** 本数据未源自其他公开数据集。 **推荐引用格式** DOI: 10.57760/sciencedb.02448 ## 数据与文件概览 **文件列表** 表3：半瓶水与半瓶油的液氮变体自由落体实验 表4：不同动物/植物存活样本与对应死亡样本的自由落体实验 表5：同一批次绿豆与大豆原始种子与萌发种子的自由落体实验 表6：表4样本的液氮变体实验 表7：人类在商用10米跳台与金属杆的自由落体对比实验 表8：动物性行为前后的自由落体实验 补充视频1：阿波罗15号月球落体实验片段（1971年由宇航员大卫·斯科特完成） 补充视频2：自由悬挂软弹簧释放后的运动过程 补充视频3：金属链与等长软弹簧从7.05米高度下落的FHD对比 补充视频4：半瓶油与半瓶水从7.04米高度下落的FHD（由加拿大宾顿市多塞特公立学校一名6岁幼儿园女童拍摄） 补充视频5：用于定义生物惯性的生物量子路径实验 补充视频6：煮熟的苹果与存活苹果从7.04米高度下落的FHD（由加拿大宾顿市多塞特公立学校一名6岁幼儿园女童拍摄） 补充视频7：大鼠与金属重物从7.04米高度下落的FHD对比 补充视频8：浸泡24小时的大豆种子与原始种子从7.04米高度下落的FHD对比（原笔误为FDH） 补充视频9：合规跳水姿势1 补充视频10：合规跳水姿势2 补充视频11：用于增强脊椎表面张力的传统功法训练 ## 方法学信息 **数据采集与生成方法** 详见关联论文的实验部分：(http://doi.org/10.21275/SR21829103822) **数据处理方法** 直接使用摄像机记录FHD，按论文所述方式手动采集数据。 **数据解读所需仪器与软件信息** 摄像机、支架、金属杆、激光测距仪、冰淇淋夹、安全绳、液氮罐及其他配套配件。 **标准与校准信息** 激光测距仪遵循厂商校准标准。植物样本需固定于支架5分钟以稳定状态，且实验需选择无风环境。对于液氮过夜处理的样本，稳定时间设置为20秒，而非常规的5分钟。动物测试中，需尽量避免落体过程中出现额外身体动作，例如捆绑翅膀等。需注意，性行为对FHD的影响不可忽视，需至少提前一周避免此类干扰。对于10米跳台的人类自由落体测试，仅允许采用补充视频9与10中的两种跳水姿势，但这两种姿势仍非理想状态，论文中建议采用手持横杆的姿势进行FHD测试，该姿势可获得可靠结果。 **实验环境条件** 需避免风或气流的影响，预留足够的稳定时间，并遵循上述标准与校准要求。本研究中的实验仅为验证FHD存在的初步实验，要获得可提供有效信息的全生命周期FHD标准曲线，仍有大量工作待完成。 **数据质量保障流程** 所有实验均尽量在同日同条件下重复，并在同一地点的不同日期开展重复实验，仅采用具有足够重现性的结果。由于10米跳台人类跳水测试仅获得一次测试机会，因此无不同日期的结果可供对比。但仍强烈建议构建全生命周期FHD标准曲线以反映生物惯性。 **参与人员** 赖亦宇、邢静丽、翁荣永、赖光新。 ## 各表格专属信息 ### 【表3 专属信息】 变量数：4；样本数/行数：6 变量列表：<瓶型：330ml、500ml；液氮处理：过夜处理、未处理；瓶内内容物：商用植物油、水；下落高度：5.28m、7.04m、23.56m> 缺失数据代码：<NA> 专用格式与缩写说明：NA 注：本研究中FHD的单位为厘米。 预实验：将目视等量的半瓶水与半瓶油组成实验组对，从一定高度释放，通过摄像机计算FHD（下落高度差）。全球范围内共开展600组此类实验（合计1200个瓶体），所有实验的下落高度均大于20cm，结果均为油瓶先落地。以其中一组为例，油瓶重量为173.274g，水瓶重量为184.125g，由于密度差异，所有实验组的油瓶均轻于水瓶，且更轻的瓶体先落地。该600组实验的参数包括：下落高度4.82m至23.65m；瓶型330ml、500ml、750ml；油品类型：菜籽油、植物油、葵花籽油、花生油、大豆油、汽车机油；测试地点：加拿大安大略省、中国贵州省。 正式液氮变体实验：选取24个商用饮用水瓶（12个330ml、12个500ml），组成12组实验组对（每组包含半瓶油与半瓶水，瓶内液面高度一致），其中6组经液氮过夜处理，6组未处理。从5.28m、7.04m、23.65m高度释放，对应FHD数据见表3。正常实验组的稳定时间为5分钟，液氮处理组的稳定时间为20秒。未处理的6组实验组均呈现FHD，且油瓶先落地；而经液氮过夜处理的6组实验组中，水瓶与油瓶同时落地。该结果证实，瓶内液体的内部运动对FHD起到关键作用。 ### 【表4 专属信息】 变量数：3；样本数/行数：34 变量列表：<物种：34种；存活状态：存活、死亡（部分实验用金属杆替代死亡样本）；重复次数：每个物种3次重复；下落高度：7.04m> 缺失数据代码：<NA> 专用格式与缩写说明：spl表示每个样本进行3次重复实验。 表4：通过对比不同存活动物与植物样本及其对应死亡样本（或金属杆）的FHD，证实二者间存在显著差异，实验重复3次。该结果验证了生物系统存活与死亡状态下的引力结合能存在差异（相较于卡文迪许实验，该实验设计的优势在于可获取体内引力波或生物惯性。正是该实验设计催生了人体体内引力波/生物惯性的测试方法，并为本研究奠定了理论基础）。 ### 【表5 专属信息】 变量数：2；样本数/行数：4 变量列表：<种子类型：绿豆、大豆；萌发状态：未萌发、浸水24小时、浸水48小时；下落高度：7.04m> 缺失数据代码：<NA> 专用格式与缩写说明：spl表示每个样本进行3次重复实验。 表5：将原始绿豆种子、大豆种子，以及浸水24小时、48小时的种子置于离心管中，从一定高度释放。实验结果显示原始种子先落地，说明种子萌发过程中积累的引力结合能高于原始种子，且该差异可通过FHD测试灵敏检测到。 ### 【表6 专属信息】 变量数：2；样本数/行数：10 变量列表：<下落高度：5.48m、7.54m；物种：苹果、梨、番茄、龙虾、小鼠> 缺失数据代码：<NA> 专用格式与缩写说明：<NA> 表6：表4已证实生物的死亡与存活状态间存在FHD差异。本实验选取表4中的部分实验组对，经液氮过夜处理后，表4中观测到的FHD恢复至0，该结果证实生物的FHD确实源于内部运动。 ### 【表7 专属信息】 变量数：1；样本数/行数：8 变量列表：<下落高度：10m；测试者：8名志愿者；仅允许采用两种非理想跳水姿势> 缺失数据代码：<无缺失数据，但理想跳水姿势应采用手持横杆的支架姿势，由于缺乏该设备，我们不得不采用两种次优姿势> 专用格式与缩写说明：<NA> 表7：人类在商用10米跳台进行跳水并与金属杆进行自由落体对比，实验结果显示存在显著FHD差异。结合此前的实验，该结果表明FHD测试是一种可靠的生物惯性或综合健康状态检测方法。强烈建议采用全生命周期FHD标准曲线用于健康监测与评估。 ### 【表8 专属信息】 变量数：1；样本数/行数：5 变量列表：<实验动物：3只1岁公鸡、2只1岁公兔；下落高度：公鸡5.28m，家兔5.44m；测试阶段：性行为前、性行为后> 缺失数据代码：<NA> 专用格式与缩写说明：spl表示性行为前的FHD进行3次重复取平均值，性行为后仅进行1次FHD测试以计算损失值。 表8：选取外观健康的1岁雄性动物，与雌性隔离饲养1个月后，先进行3次自由落体至蹦床的测试，取平均值作为性行为前的FHD。待其完成性行为后，再次测试FHD以计算性行为导致的FHD损失。所有动物在性行为后均表现出显著的FHD变化，这与传统功法的经验一致：性行为会导致雄性生物的引力结合能或生物惯性显著流失（根据传统健身经验，雄性动物在性行为后会大幅流失引力结合能，而雌性动物则会获得部分引力结合能。在武当功法体系中，对男性有严格的性行为限制，但对女性几乎无限制。通过本FHD测试可轻松检测雄性动物性行为后的引力结合能流失情况，但检测雌性动物性行为后的引力结合能积累情况仍存在难度，可能需要进一步的技术改进）。