Origami unfolds student power
The ancient art of origami to has been used to solve engineering dilemmas, build better buildings, and creatively solve medical problems; these examples express only a few ways this ancient art transpires into modernity. Its exotic appeal makes origami universally appealing to all levels of students, but also enhances mathematical concepts and visual output. For the student, manipulation of paper enhances metacognitive development of students they address real world applications. Simultaneously, the kinesthetic incorporation of origami enhances and prolongs understanding of mathematical, scientific, and engineering principles. The power origami epitomizes unfolds when the origami creation folds. This synergy results in the students seeing their creation manifest into a practical application
Power has great influence over something else, and this influence could be positive or negative, depending on the initial action of power. However, our knowledge, understanding and presence as educators make us astute power conductors. Through our ability to both control and convey power, we act as the transformers of learning, synthesizing students’ metacognition with high-volt authentic student performance. But the proof of this power is entirely derived from the actions of origami itself - through artistic expression, ideas can be visually represented. Beyond that, the power of origami exudes as students share their creative solutions to authentic problems derived from mathematics, science, and engineering. Origami is powerful as it increases spatial awareness, fine motor control, helps concentration and promotes interpretation of verbal and written instructions.
When you consider defining power as an educator, immediately one considers the ability to effect positive change within a student’s learning potential. The kinetic energy exuding with an educator into the delivery of a lesson manifests in the output displayed by the student population educated. Power does not manipulate instruction; rather power enhances instruction by tapping into the differentiated needs of a student population to emit the brightest examples of learning optimization. This optimization should be authenticated through collaboration with others. Student practitioners of origami seeking to solve real world problems solve connect with professionals in the field of engineering, architecture, and medicine as well as their peers to enhance origami applications in real world situations.
Power has great influence over something else, and this influence could be positive or negative, depending on the initial action of power. However, our knowledge, understanding and presence as educators make us astute power conductors. Through our ability to both control and convey power, we act as the transformers of learning, synthesizing students’ metacognition with high-volt authentic student performance. But the proof of this power is entirely derived from the actions of origami itself - through artistic expression, ideas can be visually represented. Beyond that, the power of origami exudes as students share their creative solutions to authentic problems derived from mathematics, science, and engineering. Origami is powerful as it increases spatial awareness, fine motor control, helps concentration and promotes interpretation of verbal and written instructions.
When you consider defining power as an educator, immediately one considers the ability to effect positive change within a student’s learning potential. The kinetic energy exuding with an educator into the delivery of a lesson manifests in the output displayed by the student population educated. Power does not manipulate instruction; rather power enhances instruction by tapping into the differentiated needs of a student population to emit the brightest examples of learning optimization. This optimization should be authenticated through collaboration with others. Student practitioners of origami seeking to solve real world problems solve connect with professionals in the field of engineering, architecture, and medicine as well as their peers to enhance origami applications in real world situations.