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5: Problem Solving

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    • 5.1: Problem Solving
      An introduction to problem-solving is the process of identifying a challenge or obstacle and finding an effective solution through a systematic approach. It involves critical thinking, analyzing the problem, devising a plan, implementing it, and reflecting on the outcome to ensure the problem is resolved.
    • 5.2: George Pólya's Strategy
      Polya's problem-solving strategy involves four key steps: understanding the problem, devising a plan, carrying out the plan, and reviewing the solution. This approach encourages students to break down problems systematically, apply various strategies, and reflect on their solutions to enhance their mathematical thinking.
    • 5.3: John Van de Walle's Strategy
      Van de Walle's problem-solving strategy involves active engagement, exploration, and reflection, encouraging students to use multiple strategies, make connections, and discuss their ideas to develop a deep understanding of mathematics. His student-centered methods focus on real-world applications and collaborative learning.
    • 5.4: Marilyn Burns' Strategy
      Marilyn Burns' problem-solving strategy emphasizes understanding the problem, choosing and applying appropriate strategies, and reflecting on the solution process. She advocates for hands-on activities and discussions that help students develop a deeper understanding of mathematical concepts and build their problem-solving skills.
    • 5.5: Use a Problem-Solving Strategy
      Applying problem-solving strategies to various math problems.
    • 5.6: Recognizing Patterns
      Recognizing patterns in mathematics is a fundamental skill that simplifies problem-solving by revealing underlying structures and relationships. This section explores various types of patterns, including numerical, visual, and algebraic, and provides strategies for identifying and applying them to enhance mathematical understanding and problem-solving efficiency.
    • 5.7: Beware of Patterns!
      The “Look for Patterns” strategy can be particularly appealing, but you have to be careful! Do not forget the “and Explain” part of the strategy. Not all patterns are obvious, and not all of them will continue.
    • 5.8: Careful Use of Language in Mathematics
      Mathematics involves not just solving problems, but also validating and communicating solutions. This process includes solving the problem, verifying the solution, and explaining it to others.
    • 5.9: Exercises and Applications

    5: Problem Solving is shared under a CC BY-NC 4.0 license and was authored, remixed, and/or curated by LibreTexts.

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