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作者:王清一 · 更新日期:2025-06-21
简剑勋的八字:乙 🐺 酉、丙、子、戊子辛 🌼 亥
1. 日柱戊 🐺 子
戊土日 🐞 元,生,于,子,月不得令得年柱乙酉生扶但年柱为财星生扶无 🌸 力。
子水为印 🐈 星,但,被日支子水伏 🐒 吟克 🌹 制印星力量弱。
日柱戊子干支相克,说,明 🌼 命主性格 🌵 刚强倔强容易衝动 ☘ 行事。
2. 年柱乙 ☘ 酉
乙木为食神,生,于,子月不得令得 🦋 日柱戊 🦢 子生扶但力量 🐎 较弱。
酉 🐘 金为正 🐕 财,生,于 🦍 ,子月不得令被日柱戊子克制财星力量弱。
年柱乙 🌾 酉财生食伤,说,明命主有食伤生财的格局有赚钱的 🌹 才能。
3. 月柱 🌻 丙 🌿 子
丙火为正 🐅 官,生,于,子月 🌸 不得 🦉 令被日支子水克制官星力量弱。
子 🐝 水为印 🦉 星,但,被日支子水伏吟克制印星力量弱。
月柱丙子官印相生,说,明,命主有官 🦁 贵之运但官星力量弱仕途的 🐝 发展受 🦁 限。
4. 时 🐋 柱辛亥
辛金为伤官,生,于,子月不得令 🍁 得 🌼 年柱乙酉生扶力量较弱。
亥水为正印,生,于子月得令 🐞 力量强。
时柱辛亥伤官生印,说 🌾 ,明,命主有伤官吐秀的 🦅 格局有才华但傲 🦊 气较重。
综合分析:简剑勋的八字,以,戊,土,日,元,生于子月不得 🐱 令全局财星弱印星受克官星力量弱伤官生印。
整体来看,命,主性格刚强倔强容易衝动行 🦍 事。有,食。伤,生。财,的,格。局有赚钱的才能仕途发展受限但有官贵之运有伤官吐秀的格局有才华但傲气较重
此说法不正确。许 🐺 。世勋比简剑勋大三岁
简剑勋 🌻 个人简介
姓 🌷 名 🕸 : 简 🐼 剑勋
出生日期 🌹 : 1963年 🐎 8月 🌹 日1
国籍: 中华人民 🐎 共 🪴 和国
职业 🦊 : 企业家、慈 🐕 善家
教育背景:1985年,毕业于上海交通大学船舶工 🐶 程专 🐼 业
1989年 🪴 ,获得英国伦敦大学帝国理工学院运筹 🐳 学硕 🐟 士学位
职业经历:1991年,创 🐬 立上海实业 🦄 集团
1996年,创立上海复星高科 🐺 技(集团)有,限公司后更名为复星国际有限公司 🐘
2007年,复星国 🦊 际在香港联 🌵 交所上 🐧 市
现任复星 🐡 国际董事长兼首席执行官
慈善事业:2007年,创,立上海 🌵 联仁 💮 社会慈善 🐱 总会后更名为复星基金会
复星基金会专注于医疗、教、育文化 🦈 和环境保护等领域的慈善项目
2019年,复星基金会捐赠10亿元人民币支持抗 🐴 击 🐵 新冠肺炎疫情
其他成就:2006年,当选为全国工商联副主 🦆 席
2009年,当选 🐬 为全国政 🐵 协委员
2013年,荣获上海 🌾 市“白玉兰荣 🦄 ”誉 ☘ 奖
2016年,荣获“上海 🕸 市优秀企业家”称号 🌼
2022年 🦊 ,入选《财 🌻 富》全球50位最具影响力 🌲 商业领袖榜单
申 🌳 请 🐠 日 🐦 期:
公 💮 开日期 🌻 :
发明 🦟 人 🕸 :JIANSHUN HSU
分类 🐦 号:G06F9/38
专利名 🐳 :Optical feedback delay array
专利类 🦊 型:授权 🐅 专利 🦊
摘要:The present invention relates to an optical feedback delay array. More particularly, the invention relates to an optical feedback delay array having a high signal to noise ratio and being capable of providing a high density of taps in a compact package.
The invention is directed to an optical feedback delay array and, more particularly, to an optical feedback delay array having a high signal to noise ratio and being capable of providing a high density of taps in a compact package.
A feedback delay array is a circuit that provides a series of delayed versions of an input signal. The delay between the taps is typically fixed and the number of taps is also fixed. Feedback delay arrays are used in a variety of signal processing applications, such as beam forming, signal cancellation, and frequency synthesis.
Conventional feedback delay arrays are typically implemented using digital circuits. Digital feedback delay arrays have the advantage of being very flexible, but they also have the disadvantage of being relatively slow and powerhungry. In addition, digital feedback delay arrays typically have a low signal to noise ratio.
The present invention overcomes the limitations of conventional feedback delay arrays by providing an optical feedback delay array. Optical feedback delay arrays have the advantage of being very fast, powerefficient, and having a high signal to noise ratio. In addition, optical feedback delay arrays can be made very compact, which makes them ideal for use in highdensity applications.
The optical feedback delay array of the present invention comprises a plurality of optical delay lines. Each optical delay line comprises a waveguide that is coupled to a reflective element. The reflective element is positioned at a distance from the waveguide that is equal to the desired delay. The input signal is coupled to the first optical delay line. The light from the input signal is reflected by the reflective element and travels through the waveguide. The light from the input signal is then coupled to the second optical delay line. The light from the second optical delay line is reflected by the reflective element and travels through the waveguide. This process continues until the light from the input signal has traveled through all of the optical delay lines. The output signal is the sum of the light from all of the optical delay lines.
The optical feedback delay array of the present invention has a number of advantages over conventional feedback delay arrays. First, the optical feedback delay array of the present invention is very fast. The delay between the taps is determined by the length of the waveguides. Light travels through waveguides very quickly, which means that the delay between the taps can be very small. Second, the optical feedback delay array of the present invention is very powerefficient. The optical feedback delay array of the present invention only uses a small amount of power to operate. Third, the optical feedback delay array of the present invention has a high signal to noise ratio. The light from the input signal is not amplified as it travels through the waveguides. This means that the signal to noise ratio of the output signal is very high. Finally, the optical feedback delay array of the present invention can be made very compact. The waveguides and reflective elements can be made very small, which means that the optical feedback delay array of the present invention can be packaged in a very small space.
The optical feedback delay array of the present invention is ideal for use in a variety of signal processing applications. The optical feedback delay array of the present invention can be used in beam forming, signal cancellation, and frequency synthesis. The optical feedback delay array of the present invention can also be used in optical communications.
