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関連する概念動画

Classifying Matter by Composition03:35

Classifying Matter by Composition

91.7K
Matter: Pure Substances and Mixtures
According to its composition, the matter can be classified into two broad categories — pure substances and mixtures. 
A pure substance is a form of matter that has a constant composition throughout with uniform properties. For example, any sample of sucrose has the same composition and same physical properties, such as melting point, color, and sweetness, regardless of the source from which it is isolated. 
A mixture is composed of two or...
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Classifying Matter by State02:49

Classifying Matter by State

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Chemistry is the study of matter and the changes it undergoes. Matter is anything that has mass and occupies space. Matter is all around us; the air, water, soil, mountains, even our bodies are all examples of matter. Matter is divided into three states — solid, liquid, and gas — that are commonly found on earth. The fourth state of matter, plasma, occurs naturally in the interiors of stars. 
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How Data are Classified: Numerical Data00:59

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Data that are countable or measurable in specific units are called numerical or quantitative data. Quantitative data are always numbers. Quantitative data are the result of counting or measuring the attributes of a population. Amount of money, pulse rate, weight, number of people living in a town, and number of students who opt for statistics are examples of quantitative data.
Quantitative data may be either discrete or continuous. All quantitative data that take on only specific numerical...
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How Data are Classified: Categorical Data01:11

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A variable, usually notated by capital letters such as X and Y, is a characteristic or measurement that can be determined for each member of a population. Data are the actual values of variables. They may be numbers, or they may be words. Datum is a single value.
Data are classified based on whether they are measurable or not. Categorical data cannot be measured; instead, it can be divided into categories. For example, if Y denotes a person's party affiliation, some examples of Y include...
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Avoidance Learning and Learned Helplessness01:14

Avoidance Learning and Learned Helplessness

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Avoidance learning and learned helplessness are critical concepts in understanding behavioral responses to negative stimuli.
Avoidance learning occurs when an organism learns that a specific behavior can prevent an unpleasant outcome. For example, a student who receives a bad grade may start studying harder to avoid future poor grades. This behavior persists even when the negative outcome is no longer present. Avoidance learning is powerful because it maintains behavior in the absence of the...
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Overview of Advanced Functional Groups02:22

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Functional groups are groups of atoms with specific chemical properties that occur within organic molecules and are sometimes denoted as “R”. Functional groups can “functionalize” a compound by enabling it to adopt different physical and chemical properties.
Types of Advanced Functional Groups
The table below summarizes some of the major functional groups in organic chemistry.
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パノラマ放射線写真から歯科疾患を分類するための高度なディープラーニングモデル.

Deema M Alnasser1, Reema M Alnasser1, Wareef M Alolayan1

  • 1Department of Information Technology, College of Computer, Qassim University, Buraydah 52571, Saudi Arabia.

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PubMed
まとめ
この要約は機械生成です。

先進的なディープラーニングモデルは,パノラマ放射線写真から歯科疾患を正確に分類します. InceptionV3モデルは優れた性能を示し,効率的な自動歯科診断の道を開きました.

キーワード:
人工知能 (AI) とは,人工知能 (AI) に関するディープラーニングの方法歯科疾患 歯科疾患 歯科疾患画像の分類 画像の分類医学画像検査 医学画像検査神経ネットワークは,ニューラルネットワークです.

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科学分野:

  • 歯科における人工知能
  • 医学画像分析 医学画像分析
  • 医療のためのディープラーニング

背景:

  • 歯科疾患は,重要な口腔衛生上の課題となり,早期診断が必要となる.
  • パノラマ放射線撮影は,自動診断システムに適した,歯の構造の詳細な可視化を提供します.
  • 既存のデータセットは,しばしばクラス不均衡と不一致に苦しんでおり,正確な自動診断を妨げています.

研究 の 目的:

  • 歯科疾患のサブ診断レベルでのマルチクラス分類のための高度なディープラーニングモデルの有効性を調査する.
  • パノラミックX線写真データセットにおけるデータ不一致とクラス不均衡に対処するため.
  • 歯科疾患の分類のための様々なコンボリューションニューラルネットワークアーキテクチャのパフォーマンスを評価する.

主な方法:

  • 35のクラスに統合された高品質のパノラマX線写真10,580のデータセットを使用しました.
  • クラス統合,誤った表示の訂正,冗長性の除去,およびクラス不均衡を軽減するための拡張を含む適用された事前処理技術.
  • InceptionV3, EfficientNetV2, DenseNet121, ResNet50,および VGG16.の5つのコンヴォルションニューラルネットワーク (CNN) アーキテクチャを評価しました.

主要な成果:

  • InceptionV3は97.51%の精度と96.61%の平均精度 (mAP) で最高性能を達成しました.
  • EfficientNetV2とDenseNet121も,それぞれ97.04%と96.70%の精度で,強力な分類パフォーマンスを示しました.
  • ResNet50とVGG16は競争力のある精度率を提供し,複数のCNNアーキテクチャの可能性を強調しました.

結論:

  • ディープラーニングモデル,特にInceptionV3は,パノラマX線写真を用いた歯科疾患の自動分類に非常に効果的です.
  • この研究は,歯科における効率的で正確な自動診断システムを開発するための基盤を提供します.
  • 将来の研究は,データセットの拡張,アンサンブル学習,および臨床的有用性を高めるための説明可能なAIに焦点を当てるべきです.