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関連する概念動画

Zener Diodes01:16

Zener Diodes

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Zener diodes are specialized semiconductor devices designed to operate in the reverse breakdown region, where they allow current to flow into the cathode, making it positive relative to the anode. This reverse operation distinguishes Zener diodes from conventional diodes and enables their use in various applications, most notably as voltage regulators. One of the defining characteristics of Zener diodes is their nearly vertical I-V (current-voltage) characteristic curve above a certain...
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The Ideal Diode01:15

The Ideal Diode

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A diode is a semiconductor device that allows current to flow in one direction only, making it a crucial component in electronic circuits for controlling the direction of current flow. An ideal diode is a simplified version of a real diode used to understand how diodes work in circuits. It possesses two terminals: the positive anode and the cathode, which is negative. When a positive voltage is applied to the anode relative to the cathode, the diode is in a forward-biased state, allowing...
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Diode: Forward bias01:20

Diode: Forward bias

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In semiconductor devices, diodes play a crucial role in directing current flow, and its operation is primarily categorized into forward bias and reverse bias. A diode is said to be forward-biased when its p-type region is connected to the positive terminal of a battery and its n-type region is linked to the negative terminal. This configuration reduces the potential barrier within the diode, allowing current to flow easily from the p to the n-type region.
The behavior of a diode in forward bias...
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Modeling of Diode Forward Characteristics01:19

Modeling of Diode Forward Characteristics

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Understanding the behavior of diodes when forward-biased is a fundamental aspect of electronic circuit design and analysis. This analysis primarily utilizes two models: the exponential diode model and the constant-voltage-drop model. The exponential model comes into play when the source voltage exceeds 0.5 volts, pushing the diode current to rise exponentially above the saturation current. This relationship is graphically depicted in the current-voltage (I-V) curve, illustrating the diode's...
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Diode: Reverse bias01:14

Diode: Reverse bias

1.9K
A diode is reverse-biased when the positive terminal of an external voltage source is connected to the n-type material and the negative terminal to the p-type material. This configuration opposes the natural direction of current flow through the diode, effectively increasing the width of the depletion region and the barrier potential. The reverse bias condition produces a minimal leakage current, primarily due to minority charge carriers. This leakage becomes significant when the reverse...
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Small-signal Diode Model01:18

Small-signal Diode Model

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In analyzing the behavior of diodes in circuits, the relationship between the current through a diode and the voltage across it is of particular interest, especially when considering the effect of a direct current (DC) bias voltage. When applied, this DC bias influences the diode's operating point, known as the Q point, around which the current-voltage (I-V) characteristic of the diode exhibits exponential behavior. Introducing a small, time-varying signal on top of this bias aids in examining...
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Updated: Jan 28, 2026

A Photonic System for Generating Unconditional Polarization-Entangled Photons Based on Multiple Quantum Interference
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単一光子アバランシェダイオードイメージングセンサーを用いた subsurface蛍光ライダー

Petr Bruza1, Arthur Petusseau1, Arin Ulku2

  • 1Thayer School of Engineering, Dartmouth College, Hanover, New Hampshire 03766, USA.

Optica
|January 26, 2026
PubMed
まとめ
この要約は機械生成です。

本研究では、組織のような散乱材料の深部にある蛍光分子を正確に検出するために、大規模な単一光子アバランシェダイオードアレイを使用した新しい技術であるサブサーフェス蛍光ライダーを紹介します。

キーワード:
単一光子アバランシェダイオード蛍光ライダーサブサーフェスイメージング散乱媒質バイオメディカルイメージング

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科学分野:

  • 生物医学光学
  • フォトニクス
  • 蛍光イメージング

背景:

  • 散乱媒質におけるサブサーフェスイメージングは困難です。
  • 蛍光分子の正確な局在化と定量化は、診断に不可欠です。
  • 既存の技術には、深度精度と解像度の限界があります。

研究 の 目的:

  • サブサーフェス蛍光ライダー(LiDAR)システムを開発すること。
  • 分子検出のためにサブミリメートルの深度精度を達成すること。
  • 散乱組織中の蛍光分子濃度の定量化を可能にすること。

主な方法:

  • 大判単一光子アバランシェダイオードアレイを利用しました。
  • サブサーフェス測定用の蛍光ライダーシステムを実装しました。
  • 信号処理と深度局在化のためのアルゴリズムを開発しました。

主要な成果:

  • 散乱媒質中でのサブサーフェス蛍光検出に成功しました。
  • 重度に散乱する媒質中でサブミリメートルの深度精度を達成しました。
  • 蛍光分子濃度を特定し、定量化することに成功しました。

結論:

  • 開発されたサブサーフェス蛍光ライダーシステムは、高い深度精度を提供します。
  • この技術は、バイオメディカルイメージングと診断に応用される可能性があります。
  • 単一光子アバランシェダイオードアレイは、困難な環境での精密な検出を可能にします。