Responsible Curious Self-directed Challenges the teacher Sees school as an opportunity Critical thinkers Risk takers Hard working Reflective Self awareness.

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Presentation transcript:

Responsible Curious Self-directed Challenges the teacher Sees school as an opportunity Critical thinkers Risk takers Hard working Reflective Self awareness Good sense of humour Basic human kindness Passion drive to succeed Elicits discussion Good work ethic Works well with others Thinkers Good communicators

CONCEPTUALIZING AND ACTUALIZING THE NEW CURRICULUM Peter Liljedahl

BC Curriculum Revisions 1968ish → what 1976ish → what 1984ish → what + how 1994ish → what + how 2003ish → what + how 2008ish → what + how 2015ish → how + what

MATHEMATICS 1 Foundations and Pre-Calculus Reasoning and analyzing Inductively and deductively reason and use logic to explore, make connections, predict, analyze, generalize, and make conclusions Estimate Develop and apply mental math strategies Use tools {appropriate technology) to explore and create patterns, examine relationships, and test conjectures Understanding and solving Implement multiple strategies to solve problems in both abstract and real-life situations using different cultural perspectives Develop, construct, and apply mathematical understanding through play, inquiry, and problem solving Communicating and representing Use mathematical vocabulary and language to contribute to mathematical discussions Communicate in a variety of ways Explain, clarify, and justify mathematical ideas Develop mathematical understanding through concrete, pictorial, and symbolic representations Use technology appropriately to record, communicate, and represent thinking Connecting and reflecting Visualize and describe mathematical concepts Explore, apply, and connect mathematical concepts to each other and make mathematical connections to other disciplines and the real world Use dynamic visualizations to explore geometric and graphical relationships Use mathematical arguments to support personal choices and recognize the consequences Apply cultural perspectives of First Peoples to the concepts of locating, measuring, and numbering strategies to solve puzzles and win games primary trigonometric ratios metric and imperial measurement conversions analysis of measures of central tendency, including outliers experimental probability income, including taxes and deductions savings and compound interest area and volume relations among data, graphs, and situations powers with integral exponents multiplication of polynomial expressions common factors and trinomial factoring linear equations with rational coefficients linear relations

SCIENCE 9 Questioning and predicting Demonstrate a sustained intellectual curiosity about a scientific topic or problem of personal interest Make observations aimed at identifying their own questions, including increasingly abstract ones, about the natural world Formulate multiple hypotheses and predict multiple outcomes Planning and conducting Collaboratively and personally plan, select, and use appropriate investigation methods, including field work and lab experiments, to collect reliable data (qualitative and quantitative) Assess risks and address ethical issues associated with their proposed methods Select and use appropriate equipment, including digital technologies, to systematically and accurately collect and record data Processing and analyzing data and information Experience and interpret the local environment Seek and analyze patterns, trends, and connections in data, including describing relationships between variables and identifying inconsistencies Use knowledge of scientific concepts to draw conclusions that are consistent with evidence Analyze cause-and-effect relationships Evaluating Evaluate their methods and experimental conditions, including identifying sources of error or uncertainty, confounding variables, and possible alternative explanations and conclusions Describe specific ways to improve their investigation methods and the quality of the data Evaluate the validity of and limitations of a model or analogy in relation to the phenomenon modelled Demonstrate an awareness of assumptions, question information given, and identify bias in their own work and secondary sources Consider the changes in knowledge over time as tools and technologies have developed Exercise a healthy, informed skepticism and use scientific knowledge and findings to form their own investigations to evaluate claims in secondary sources Consider social, ethical, and environmental implications of the findings from their own and others’ investigations Critically analyze the validity of information in secondary sources and evaluate the approaches used to solve problems Applying and innovating Contribute to care for self, others, community, and world through personal or collaborative approaches Co-operatively design projects with local and/or global connections and applications Transfer and apply learning to new situations Generate and introduce new or refined ideas when problem solving Contribute to finding solutions to problems at a local and/or global level through inquiry Communicating Formulate physical or mental theoretical models to describe a phenomenon Communicate scientific ideas, information, and perhaps a suggested course of action for a specific purpose and audience, constructing evidence-based arguments and using appropriate scientific language, conventions, and representations Express and reflect on a variety of experiences, perspectives, and worldviews of place asexual reproduction:mitosis different forms sexual reproduction:meiosis human sexual reproduction element properties as organized in the periodic table an element’s properties are related to the arrangement and energy of its electrons and to its atomic size circuits — must be complete for electrons to flow voltage, current, and resistance effects of solar radiationon the cycling of matter and energy matter cycles within biotic and abiotic components of ecosystems sustainability of systems and First Peoples’ principles ofinterconnectedness

THINKOLOGY & LEARNIFICATION 9

TEACHING AT THE INTERSECTIONS Unintended Consequences

GOOD ACTIVITIES Then and Now

How did you estimate..? Explain how the referent helped you…? Is the total closer to 5 or 10? When might you need to partition numbers? What strategies did you use to solve the problem? How would you justify your solution? _________________________________________________________________ When you explored ways to …, how can you prove that you have the same ….? When might you need to …? How many ways..? Show your strategies. How might you apply what you learned...? Why did you choose a specific strategy? _________________________________________________________________ What did you notice? How could you represent you thinking (concretely, pictorially, symbolically)? How would you explain the strategy you used? Explain how you solved the problem. Explain what you learned. Draw a picture to show your thinking. How would you describe your solution? How would you model the concept and explain your thinking to others? Describe and compare… How would you interpret the relationships…? Explain how you know… Why does this make sense? Explore representing and describing … What did you notice? How did you use technology to explore…? How did you use technology to solve the problem? How did you use technology to communicate and represent your thinking? Express your thoughts about your discoveries. _________________________________________________________________ How did you visualize to help solve the problem? Describe what you visualized when you were solving the problem. When might you use what you have learned? How might this connect to other mathematical concepts? How might you apply what you have learned? Demonstrate how you know this can be applied to other situations. How is this problem like something you solved before?

GOOD ACTIVITIES Then and Now What did you notice? How could you represent you thinking (concretely, pictorially, symbolically)? How would you explain the strategy you used? Explain how you solved the problem. Explain what you learned. Draw a picture to show your thinking. How would you describe your solution? How would you model the concept and explain your thinking to others? Describe and compare… How would you interpret the relationships…? Explain how you know… Why does this make sense? Explore representing and describing … What did you notice? How did you use technology to explore…? How did you use technology to solve the problem? How did you use technology to communicate and represent your thinking? Express your thoughts about your discoveries.

ASSESSMENT Then and Now

THANK YOU!