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関連する概念動画

Nonconscious Mimicry01:13

Nonconscious Mimicry

Nonconscious mimicry occurs when individuals alter their mannerisms to match the behaviors and expressions of those nearby, without intention.
Doppler Effect - I00:56

Doppler Effect - I

The Doppler effect and Doppler shift were named after the Austrian physicist and mathematician Christian Johann Doppler in 1842, who conducted experiments with both moving sources and moving observers. Consider an observer standing on a street corner, observing an ambulance with a siren sound passing by at a constant speed. The observer experiences two characteristic changes in the sound of the siren. Initially, the sound increases in loudness as the ambulance approaches and decreases in...
Doppler Effect - II01:05

Doppler Effect - II

The Doppler effect has several practical, real-world applications. For instance, meteorologists use Doppler radars to interpret weather events based on the Doppler effect. Typically, a transmitter emits radio waves at a specific frequency toward the sky from a weather station. The radio waves bounce off the clouds and precipitation and travel back to the weather station. The radio frequency of the waves reflected back to the station appears to decrease if the clouds or precipitation are moving...
Masking and Demasking Agents01:19

Masking and Demasking Agents

EDTA titrations may necessitate masking and demasking agents to temporarily protect a particular metal ion in a mixture from the EDTA reaction. These agents facilitate the sequential analysis of the metal ions by forming stable complexes with some—but not all—metal ions during certain steps.
There are many masking agents, such as cyanide, fluoride, triethanolamine, thiourea, and 2,3-bis(sulfanyl)propan-1-ol (formerly 2,3-dimercapto-1-propanol), with the masking agent chosen based on the metal...
Echo01:06

Echo

The human ear cannot distinguish between two sources of sound if they happen to reach within a specific time interval, typically 0.1 seconds apart. More than this, and they are perceived as separate sources.
Imagine the sound is reflected back to the ears. Assuming that the source is very close to the human, the difference between hearing the two sounds—the emitted sound and the reflected sound—may be more than the minimum time for perceiving distinct sounds. If this is the case, then the...
Properties of DTFT I01:24

Properties of DTFT I

In signal processing, Discrete-Time Fourier Transforms (DTFTs) play a critical role in analyzing discrete-time signals in the frequency domain. Various properties of the DTFTs such as linearity, time-shifting, frequency-shifting, time reversal, conjugation, and time scaling help understand and manipulate these signals for different applications.
The linearity property of DTFTs is fundamental. If two discrete-time signals are multiplied by constants a and b respectively, and then combined to...

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関連する実験動画

Updated: May 7, 2026

Tracking Infiltration Front Depth Using Time-lapse Multi-offset Gathers Collected with Array Antenna Ground Penetrating Radar
07:14

Tracking Infiltration Front Depth Using Time-lapse Multi-offset Gathers Collected with Array Antenna Ground Penetrating Radar

Published on: May 1, 2018

タイムカローリングの実証.

Moti Fridman1, Alessandro Farsi, Yoshitomo Okawachi

  • 1School of Applied and Engineering Physics, Cornell University, Ithaca, New York 14853, USA.

Nature
|January 7, 2012
PubMed
まとめ

研究者は,光の分散を操作することによって,時間的な隠蔽,時間的なイベントを隠すことを実証しています. 光ファイバーシステムのこの突破は,イベント振幅を10倍以上削減し,完全な時空隠蔽の道を開く.

科学分野:

  • 物理 物理学 物理学とは
  • オプティクスは光学です.
  • 電磁気学は,電磁気学である.

背景:

  • 空間隠蔽は,物体を隠すために屈折率を操作します.
  • タイムカローリングは,光の束の"タイムホール"内の出来事を隠すことを目的としています.
  • これは,時間の経過とともに物質の分散を操作することに依存しています.

研究 の 目的:

  • 光ファイバーシステムにおける一時的隠蔽を実験的に実証する.
  • 微分と分散的拡大の間の時空二元性概念を適用する.
  • テンポラル・マントの性能を特徴付けるために.

主な方法:

  • 光束の分散を操作するために光ファイバーシステムを利用しました.
  • 探査機の光のビームの前部を加速し,後部を減速して時空の隙間を作り出しました.
  • 時空分散を制御するために時空二元性の原理を適用した.

主要な成果:

  • "タイムホール"を作り出すことでタイムカローリングを成功裏に実証しました.
  • コールドがアクティブであるとき,ピコ秒の時間スケールのイベントの振幅を1桁以上減らしました.
  • 光学相互作用による探査ビームのスペクトル変化を展示した.

さらに関連する動画

Recording Ultra-Realistic Full-Color Analog Holograms for Use in a Moving Hologram Display
09:04

Recording Ultra-Realistic Full-Color Analog Holograms for Use in a Moving Hologram Display

Published on: January 14, 2020

Demonstration of Spin-Multiplexed and Direction-Multiplexed All-Dielectric Visible Metaholograms
08:48

Demonstration of Spin-Multiplexed and Direction-Multiplexed All-Dielectric Visible Metaholograms

Published on: September 25, 2020

関連する実験動画

Last Updated: May 7, 2026

Tracking Infiltration Front Depth Using Time-lapse Multi-offset Gathers Collected with Array Antenna Ground Penetrating Radar
07:14

Tracking Infiltration Front Depth Using Time-lapse Multi-offset Gathers Collected with Array Antenna Ground Penetrating Radar

Published on: May 1, 2018

Recording Ultra-Realistic Full-Color Analog Holograms for Use in a Moving Hologram Display
09:04

Recording Ultra-Realistic Full-Color Analog Holograms for Use in a Moving Hologram Display

Published on: January 14, 2020

Demonstration of Spin-Multiplexed and Direction-Multiplexed All-Dielectric Visible Metaholograms
08:48

Demonstration of Spin-Multiplexed and Direction-Multiplexed All-Dielectric Visible Metaholograms

Published on: September 25, 2020

結論:

  • 実験的なデモは,完全な時空隠蔽に向けた重要な一歩です.
  • この結果は,一時的隠蔽のための分散を操作する概念を検証しています.
  • この研究は,光学的な方法を使用して,イベントを時間内に制御するための道を開きます.