- •Give a definition of science. Open the three values of science.
- •2. Name the criteria (features) scientific. Determine each criterion.
- •3. Expand the example of your own science structure of scientific knowledge.
- •4. Define the object and subject of research. Open these concepts as an example of your science.
- •5. Show the difference between the scientific and religious world view as the two ways of perceiving the world.
- •6. Specify the differences between science and art as the two ways of knowing.
- •7.Formulate the concept of ‘scientism’ and ‘anti-scientism’. Arguments each of them.
- •8. Identify the difference between externalism and internalism in science. Give examples of each.
- •Identify the difference between externalism and internalism in science. Give examples of each.
- •9. Evaluate the unity and specify the differences between philosophy and science as two forms of rationality.
- •10. Expand the concept "quantifier of existence".
- •11. Display the fundamental differences between scientific, anti-scientific and extra-scientific knowledge.
- •12. A comparative analysis of the concepts: information, knowledge, wisdom.
- •13. Explain the three tasks of science.
- •14. Expand the 5 points of view on the problem of the beginning of science. Explain your position on this issue.
- •15.Explain the concept of verification and falsification in the science.
- •16 Name and define the form of non-scientific knowledge. Give examples of each.
- •17. Specify the main problems described in the text "Science without hope."
- •18. Determine the ability of the productive imagination.
- •19. Give your assessment of the text ‘The phenomenon of alternative science’.
- •20. Illustrate the essence of quasi-science and para-science.
- •21. Open the myths of your science.
- •22. Analyze "outstanding issues" of your science.
- •23. Define the concept of ‘knowledge’. Name the three characteristics of knowledge.
- •24. Consider the main ideas, hypotheses and theories on the topic "Knowledge".
- •25. Define the essence of thinking and show how it differs from the mind (intellect).
- •26.Identify and expand the main features pre-science.
- •27. Formulate and expand the scientific ideas and the main program of Antiquity.
- •Identify and expand the main features pre-science.
- •28. Expand the paradigm of ancient science.
- •29. Evaluate the major achievements of science in the Middle Ages (Europe and the Arab East).
- •31.Formulate discoveries and personalities in classical science.
- •32. Formulate and expand the main ideas and principles of classical science.
- •33. Expand the paradigm of classical science.
- •34. Name and expand the main ideas and principles of non-classical science.
- •35. Name and expand the main ideas and principles of the post-non-classical science.
- •36. Make the analysis of the socio-cultural environment of Kazakhstan science (5 parameters).
- •37. Give your assessment of the intellectual level of the Kazakhstan society.
- •38. Please rate the prestige of Kazakhstan science and formulate your recommendations on this issue.
- •39. Consider the main ideas, hypotheses and theories on the topic ‘Planet earth’. The Solar Nebular Hypothesis
- •A Cloud of Gas
- •Sun Formation
- •Planet and Asteroid Formation
- •40. Consider the main ideas, hypotheses and theories on the topic "Mind & Body"
- •41. Describe the content of the videotext "Agora" and formulate your conclusions on it.
- •42. Evaluate the main issues and features an ancient science in videotext "Agora".
- •43. Expand the content of the videotext "a Beautiful Mind" and make your own conclusions on it.
- •44. Consider the problem of creativity and personality of the scientist in videotext "a Beautiful Mind."
- •45. Show in the context of the video-text "a Beautiful Mind" and other examples of the difference of genius and talent in science.
- •46. Make a glossary of basic scientific ideas and concepts in videotext "Interstellar"
- •47. Describe the content of the videotext ‘Interstellar’ and formulate your conclusion on it.
- •48. Determine the nature of scientific creativity. Formulate the paradox of creativity. Evaluate the role of intuition in scientific discovery.
- •49. Consider the main ideas, hypotheses and theories on the topic "Universe"
- •Inflation
- •Inflation
- •50. Consider the main ideas, hypotheses and theories on the topic "Human Evolution".
4. Define the object and subject of research. Open these concepts as an example of your science.
The process of science is a way of building knowledge about the universe - constructing new ideas that illuminate the world around us. Those ideas are inherently tentative, but as they cycle through the process of science again and again and are tested and retested in different ways , We become increasingly confident in them. Accident, through this same iterative process, ideas are modified, expanded, and combined into more powerful explanations. For example, a few observations about inheritance patterns in garden peas can - over many years and through the work Of many different scientists - be built into the broad understanding of genetics offered by science today. So is the process of science is iterative, ideas do not churn through it repetrast.
And that knowledge is useful for all sorts of things: from designing bridges, to slowing climate change, to prompting frequent hand washing during flu season. Scientific knowledge allows us to develop new technologies, solve practical problems, and make informed decisions — both individually and collectively. Because its products are so useful, the process of science is intertwined with those applications:
• New scientific knowledge may lead to new applications. For example, the discovery of the structure of DNA was a fundamental breakthrough in biology. It formed the underpinnings of research that would ultimately lead to a wide variety of practical applications, including DNA fingerprinting, genetically engineered crops, and tests for genetic diseases.
• New technological advances may lead to new scientific discoveries. For example, developing DNA copying and sequencing technologies has led to important breakthroughs in many areas of biology, especially in the reconstruction of the evolutionary relationships among organisms.
• Potential applications may motivate scientific investigations. For example, the possibility of engineering microorganisms to cheaply produce drugs for diseases like malaria motivates many researchers in the field to continue their studies of microbe genetics.
The process of science is a way of building knowledge about the universe — constructing new ideas that illuminate the world around us. Those ideas are inherently tentative, but as they cycle through the process of science again and again and are tested and retested in different ways, we become increasingly confident in them. Furthermore, through this same iterative process, ideas are modified, expanded, and combined into more powerful explanations. For example, a few observations about inheritance patterns in garden peas can — over many years and through the work of many different scientists — be built into the broad understanding of genetics offered by science today. So although the process of science is iterative, ideas do not churn through it repetitively. Instead, the cycle actively serves to construct and integrate scientific knowledge.
And that knowledge is useful for all sorts of things: from designing bridges, to slowing climate change, to prompting frequent hand washing during flu season. Scientific knowledge allows us to develop new technologies, solve practical problems, and make informed decisions — both individually and collectively.