{"pkgId":"25","subjectId":"1342","fullwidthLayout":false,"contentData":{"PACKAGE_NAME":"ICSE Senior Secondary School","PACKAGE_SLUG":"icse-senior-secondary-school","PACKAGE_IMG":"file_1229948183_1589535991.png","ADMCOURSE_ID":"383","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","STANDARD_NAME":"ICSE","ADMSUBJECT_ID":"1342","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","CAT_NAME":"Refracting Telescope","CONT_ID":"124","CONT_TITLE":"Refracting Telescope","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA refracting telescope is an optical device that is used to collect and observe light coming from distant objects by using two converging lenses.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- State the use of a refracting telescope.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Label the basic parts of a refracting telescope.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Trace the ray diagram used in the formation of the image of a distant object.\u003C\/div\u003E","CONT_SLUG":"refracting-telescope","BACKING_FILE":"ss400054.apk","CONT_SRC":"","CONTTYPE_ID":"9","PUBLIC_IMG":"thumb_SS400054.jpg","PUBLIC_BANNER_IMG":"SS400054.jpg","PUBLIC_VIDEO":"pvideo_ss400054.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/E8uvJ4uW_jQ","PACKAGE_DOMAIN":"STEM"},"pkgCourses":[{"ADMCOURSE_ID":"382","COURSE_NAME":"Grade 11","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1338","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":20,"contSlug":"describing-position"},{"ADMCOURSE_ID":"382","COURSE_NAME":"Grade 11","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1339","DISPLAY_NAME":"Chemistry","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":28,"contSlug":"group-2-alkaline-earth-metals"},{"ADMCOURSE_ID":"382","COURSE_NAME":"Grade 11","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1340","DISPLAY_NAME":"Biology","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Biology","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":35,"contSlug":"the-nitrogen-cycle"},{"ADMCOURSE_ID":"382","COURSE_NAME":"Grade 11","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1341","DISPLAY_NAME":"Mathematics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Mathematics","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":27,"contSlug":"cross-sections"},{"ADMCOURSE_ID":"383","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1342","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":15,"contSlug":"semiconductors"},{"ADMCOURSE_ID":"383","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1343","DISPLAY_NAME":"Chemistry","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":14,"contSlug":"concentration-pressure-and-reaction-rate"},{"ADMCOURSE_ID":"383","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1344","DISPLAY_NAME":"Biology","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Biology","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":30,"contSlug":"mutualism"},{"ADMCOURSE_ID":"383","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","ADMSUBJECT_ID":"1345","DISPLAY_NAME":"Mathematics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Mathematics","SUBJECT_NAME_AR":"","PACKAGE_ID":"25","total":18,"contSlug":"types-of-relations"}],"allContents":[{"CONT_ID":"667","CATEGORY_ID":"1","CONT_TITLE":"Semiconductors","CONT_SLUG":"semiconductors","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E  \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EMetals, are good conductors of electricity, while insulators, like diamond, do not conduct electricity, even when heated. Semiconductors, such as silicon, have conductivity between that of a conductor and an insulator. Electrical conductivity of a semiconductor increases with an increase in temperature. Semiconductors are found in many electronic devices.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E  \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E  \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Compare the electrical conductivity of a semiconductor with that of a conductor and an insulator.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the effect of temperature on the conductivity of a semiconductor.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Name common objects where semiconductors are used.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.vc000027","TOPIC_ID":"vc000027","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_vc000027.jpg","PUBLIC_BANNER_IMG":"vc000027.jpg","PUBLIC_VIDEO":"en_us_pvideo_vc000027.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/S4OnmsYGcBw","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"2143","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;p\u0026gt;Overview:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;Metals, are good conductors of electricity, while insulators, like diamond, do not conduct electricity, even when heated. Semiconductors, such as silicon, have conductivity between that of a conductor and an insulator. Electrical conductivity of a semiconductor increases with an increase in temperature. Semiconductors are found in many electronic devices.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;Learning Objectives::\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;After completing this module, you will be able to:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Compare the electrical conductivity of a semiconductor with that of a conductor and an insulator.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Identify the effect of temperature on the conductivity of a semiconductor.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Name common objects where semiconductors are used.\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Semiconductors","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"STEM"},{"CONT_ID":"474","CATEGORY_ID":"1","CONT_TITLE":"Microwaves","CONT_SLUG":"microwaves","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EMicrowaves are categorized as radio waves. They have the shortest wavelengths of all the radio waves. Microwaves are non ionizing radiations. When microwaves are in sufficient intensity they can cause molecules of the matter to vibrate which in turn cause friction and produces heat. These waves are used in cooking of food in microwave ovens. Microwaves can penetrate clouds, light rain, snow, haze and smoke. This makes them good for transmitting information from one place to another.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define and identify microwaves in the electromagnetic spectrum.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the application of microwaves.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe how cell phones and towers use microwave antennas to transmit signals.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":"ms400523.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms400523","TOPIC_ID":"ms400523","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400523.jpg","PUBLIC_BANNER_IMG":"MS400523.jpg","PUBLIC_VIDEO":"pvideo_ms400523.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/nBhSzG9wGNg","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Microwaves are categorized as radio waves. They have the shortest wavelengths of all the radio waves. Microwaves are non ionizing radiations. When microwaves are in sufficient intensity they can cause molecules of the matter to vibrate which in turn cause friction and produces heat. These waves are used in cooking of food in microwave ovens. Microwaves can penetrate clouds, light rain, snow, haze and smoke. This makes them good for transmitting information from one place to another.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define and identify microwaves in the electromagnetic spectrum.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the application of microwaves.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe how cell phones and towers use microwave antennas to transmit signals.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Microwaves","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"450","CATEGORY_ID":"1","CONT_TITLE":"Magnetic Fields","CONT_SLUG":"magnetic-fields","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe space around a magnet in which the force of attraction and repulsion can be detected is called magnetic field. The force that one magnet exerts on another can be described as the interaction between one magnet and the magnetic field of the other. Magnetic field can be detected with the help of a magnetic compass or a magnet. The imaginary lines of magnetic field around a magnet are called field line or field line of magnet.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define magnetic field.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Illustrate the magnetic field lines around a bar magnet.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Illustrate the resulting magnetic field when two magnets are brought together.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms400169","TOPIC_ID":"ms400169","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400169.jpg","PUBLIC_BANNER_IMG":"MS400169.jpg","PUBLIC_VIDEO":"pvideo_ms400169.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/YuDncuygAMw","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;The space around a magnet in which the force of attraction and repulsion can be detected is called magnetic field. The force that one magnet exerts on another can be described as the interaction between one magnet and the magnetic field of the other. Magnetic field can be detected with the help of a magnetic compass or a magnet. The imaginary lines of magnetic field around a magnet are called field line or field line of magnet.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define magnetic field.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Illustrate the magnetic field lines around a bar magnet.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Illustrate the resulting magnetic field when two magnets are brought together.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Magnetic Fields","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"382","CATEGORY_ID":"1","CONT_TITLE":"Magnetic Domains","CONT_SLUG":"magnetic-domain","CONT_TITLE_AR":"Magnetic Domain","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA magnetic domain is a region in a magnetic material in which the magnetic fields of all atoms point in the same direction. Each domain is a tiny magnet with a north pole and a south pole.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIn this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe magnetic domains.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Demonstrate the behavior of magnetic domains in different magnetic materials.\u003C\/div\u003E","CONT_DESC_AR":"\u0026lt;p\u0026gt;A magnetic domain is a region in a magnetic material in which the magnetic fields of atoms all point in the same direction. 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First is the nucleus which is very small in size and carries a positive charge, and in which the entire mass of the atom is concentrated. The second part is the extra nuclear part, in which negatively charged electrons revolve around the nucleus on fixed circular paths.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the structure of an atom according to Rutherford\u0026#039;s atomic model.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify Rutherford\u0026#039;s model of an atom.\u003C\/div\u003E","CONT_DESC_AR":"According to Rutherfords atomic model, the atom consists of two parts\u003Cbr\u003E\n1. Nucleus, very small in size, carries a positive charge and in which the entire mass of the atom is concentrated\u0026lt;br \/\u0026gt;\n2. Extra nuclear part, in which negatively charged electrons revolve around the nucleus on fixed circular paths\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nAt the end of simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the structure of an atom according\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;to Rutherford\u0026amp;#39;s atomic model\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify Rutherford\u0026amp;#39;s model of atom\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;","BACKING_FILE":"hs200040.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200040","TOPIC_ID":"hs200040","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200040.jpg","PUBLIC_BANNER_IMG":"HS200040.jpg","PUBLIC_VIDEO":"pvideo_hs200040.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/YyEDbnJd0lc","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;According to Rutherford\u2019s atomic model, the atom consists of two parts. First is the nucleus which is very small in size and\u0026amp;nbsp; carries a positive charge, and in which the entire mass of the atom is concentrated. The second part is the extra nuclear part, in which negatively charged electrons revolve around the nucleus on fixed circular paths.\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the structure of an atom according\u0026amp;nbsp; to Rutherford\u0026#039;s atomic model.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify Rutherford\u0026#039;s model of an atom.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Rutherford\u2019s Atomic Model","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"STEM"},{"CONT_ID":"124","CATEGORY_ID":"1","CONT_TITLE":"Refracting Telescope","CONT_SLUG":"refracting-telescope","CONT_TITLE_AR":"Refracting Telescope","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA refracting telescope is an optical device that is used to collect and observe light coming from distant objects by using two converging lenses.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- State the use of a refracting telescope.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Label the basic parts of a refracting telescope.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Trace the ray diagram used in the formation of the image of a distant object.\u003C\/div\u003E","CONT_DESC_AR":"A refracting telescope uses lenses to gather the light from the distant objects.\u003C\/br\u003E\u003C\/br\u003E\r\nLearning Objectives:\u003C\/br\u003E\u003C\/br\u003E\r\nIn this simulation, you will be able to:\u003C\/br\u003E\r\n- state the use of a refracting telescope\u003C\/br\u003E\r\n- label the basic parts of a refracting telescope used in the formation of the image of a distant object\u003C\/br\u003E\r\n- trace the ray diagram used in the formation of the image of a distant object","BACKING_FILE":"ss400054.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss400054","TOPIC_ID":"ss400054","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400054.jpg","PUBLIC_BANNER_IMG":"SS400054.jpg","PUBLIC_VIDEO":"pvideo_ss400054.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/E8uvJ4uW_jQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;A refracting telescope is an optical device that is used to collect and observe light coming from distant objects by using two converging lenses.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- State the use of a refracting telescope.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Label the basic parts of a refracting telescope.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Trace the ray diagram used in the formation of the image of a distant object.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Refracting Telescope","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"STEM"},{"CONT_ID":"120","CATEGORY_ID":"1","CONT_TITLE":"Simple Microscope","CONT_SLUG":"simple-microscope","CONT_TITLE_AR":"Simple Microscope","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA microscope is a device used to magnify small, close objects. It uses two convex lenses \u2013 an objective lens and eyepiece, with relatively short focal lengths.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- State the use of a microscope.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Label basic parts of a microscope used in the formation of a magnified image of a microscopic object.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Trace the ray diagram used in the formation of a magnified image of a microscopic object.\u003C\/div\u003E","CONT_DESC_AR":"A microscope is a device used to magnify small, close objects. It uses two convex lenses \u0026amp;ndash; an objective lens and eyepiece, with relatively short focal lengths.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n- state the use of a microscope\u0026lt;br \/\u0026gt;\n- label basic parts of a microscope used in the formation of a magnified image of a microscopic object\u0026lt;br \/\u0026gt;\n- trace the ray diagram used in the formation of a magnified image of a microscopic object","BACKING_FILE":"ss400053.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss400053","TOPIC_ID":"ss400053","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400053.jpg","PUBLIC_BANNER_IMG":"SS400053.jpg","PUBLIC_VIDEO":"pvideo_ss400053.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/qFLh6t1Wo7g","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;A microscope is a device used to magnify small, close objects. It uses two convex lenses \u2013 an objective lens and eyepiece, with relatively short focal lengths.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- State the use of a microscope.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Label basic parts of a microscope used in the formation of a magnified image of a microscopic object.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Trace the ray diagram used in the formation of a magnified image of a microscopic object.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Simple Microscope","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"STEM"},{"CONT_ID":"113","CATEGORY_ID":"1","CONT_TITLE":"Polarization of Light","CONT_SLUG":"polarization-of-light","CONT_TITLE_AR":"Polarisation of Light","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EPolarization of light is the phenomenon in which the vibrations of light are restricted in a direction perpendicular to the direction of the propagation of light. This phenomenon is used in polarizers, to control the intensity of light. A polarizer is generally used in sunglasses, window panes, photographic cameras, etc.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the phenomenon of the polarization of light.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define polarizers.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Determine the behavior of two polarizers kept at different angles.\u003C\/div\u003E","CONT_DESC_AR":"The phenomenon of restricting the vibrations of light, of electric field vectors, in a direction perpendicular to the direction of the propagation of light is called the polarization of light. Polarizers use this phenomenon so as to control the intensity of light. These polarizers can be used in sunglasses, windowpanes, photographic cameras, and so on.\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n- explain the phenomenon of the polarization of light\u0026lt;br \/\u0026gt;\n- define polarizers\u0026lt;br \/\u0026gt;\n- determine the behavior of two polarizers kept at different angles","BACKING_FILE":"ss400019.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss400019","TOPIC_ID":"ss400019","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400019.jpg","PUBLIC_BANNER_IMG":"SS400019.jpg","PUBLIC_VIDEO":"pvideo_ss400019.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/do5oTfai-RI","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Polarization of light is the phenomenon in which the vibrations of light are restricted in a direction perpendicular to the direction of the propagation of light. This phenomenon is used in polarizers, to control the intensity of light. A polarizer is generally used in sunglasses, window panes, photographic cameras, etc.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the phenomenon of the polarization of light.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define polarizers.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Determine the behavior of two polarizers kept at different angles.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Polarisation of Light","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"110","CATEGORY_ID":"1","CONT_TITLE":"Waves and Particles","CONT_SLUG":"waves-and-particles","CONT_TITLE_AR":"Waves and Particles","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn electromagnetic wave can behave as a particle called a photon. A photon is a massless bundle of energy that behaves like a particle and a wave. The photon\u0026#039;s energy depends on the frequency of the wave. Its energy increases as the wave\u0026#039;s frequency increases.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain that a wave can behave as a particle.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define photons.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain that a particle can behave as a wave.\u003C\/div\u003E","CONT_DESC_AR":"An electromagnetic wave can behave as a particle called a photon. A photon is a mass less bundle of energy that behaves like a particle. The photon\u0026amp;#39;s energy depends on the frequency of the wave. Its energy increases as the wave\u0026amp;#39;s frequency increases.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be to:\u0026lt;br \/\u0026gt;\n- describe that a wave can behave as a particle\u0026lt;br \/\u0026gt;\n- define photons\u0026lt;br \/\u0026gt;\n- describe that a particle can behave as a wave","BACKING_FILE":"ss400018.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss400018","TOPIC_ID":"ss400018","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400018.jpg","PUBLIC_BANNER_IMG":"SS400018.jpg","PUBLIC_VIDEO":"pvideo_ss400018.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/PI_F5l4SigQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;An electromagnetic wave can behave as a particle called a photon. A photon is a massless bundle of energy that behaves like a particle and a wave. The photon\u0026#039;s energy depends on the frequency of the wave. Its energy increases as the wave\u0026#039;s frequency increases.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain that a wave can behave as a particle.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define photons.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain that a particle can behave as a wave.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Waves and Particles","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"84","CATEGORY_ID":"1","CONT_TITLE":"Faraday\u0027s Law of Electromagnetic Induction","CONT_SLUG":"faradays-law-of-electromagnetic-induction","CONT_TITLE_AR":"Faraday\u0027s Law of Electromagnetic Induction","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe relative motion between a magnet and coil induces an electric current within the coil. This is known as Faraday\u2019s law of electromagnetism. The direction of current depends on the direction of motion and also on the direction of the pole of the magnet facing the coil.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe Faraday\u0026#039;s law of electromagnetism as the induction of an electric current in a coil due to the relative motion between a magnet and the coil.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain that the direction of current depends on the direction of motion and also on the direction of magnetic field.\u003C\/div\u003E","CONT_DESC_AR":"The relative motion between a magnet and coil induces an electric current within the coil. This is known as Faraday\u0026amp;rsquo;s Law of Electromagnetism. The direction of current depends on the direction of motion and also on the direction of the pole of the magnet facing the coil.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n- describe Faraday\u0026amp;#39;s law of electromagnetism as the induction of an electric current in a coil due to the relative motion between a magnet and the coil .\u0026lt;br \/\u0026gt;\n- explain that the direction of current depends on the direction of motion and also on the direction of magnetic field. That is, which pole of the magnet faces the coil .","BACKING_FILE":"ss400024.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss400024","TOPIC_ID":"ss400024","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400024.jpg","PUBLIC_BANNER_IMG":"SS400024.jpg","PUBLIC_VIDEO":"pvideo_ss400024.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/9ivViwxuotw","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;The relative motion between a magnet and coil induces an electric current within the coil. This is known as Faraday\u2019s law of electromagnetism. The direction of current depends on the direction of motion and also on the direction of the pole of the magnet facing the coil.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe Faraday\u0026#039;s law of electromagnetism as the induction of an electric current in a coil due to the relative motion between a magnet and the coil.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain that the direction of current depends on the direction of motion and also on the direction of magnetic field.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Faraday\u0027s Law of Electromagnetic Induction","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"66","CATEGORY_ID":"1","CONT_TITLE":"Wavelength and Frequency","CONT_SLUG":"wavelength-and-frequency","CONT_TITLE_AR":"Wavelength and Frequency","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe wavelength of a transverse wave is the distance from crest to crest or trough to trough. The wavelength of a longitudinal wave is the distance from the middle of one compression to the middle of the next one, or the distance from the middle of one rarefaction to the middle of another. Frequency is commonly measured in hertz (Hz).\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define the terms wavelength and frequency.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Distinguish between transverse and longitudinal waves.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Determine the wavelength and frequency of transverse and longitudinal waves.\u003C\/div\u003E","CONT_DESC_AR":"The wavelength of a transverse wave is the distance from crest to nearest crest or trough to nearest trough.\u0026amp;nbsp;The wavelength of a longitudinal wave is the distance from the middle of one compression to the middle of the next one or the distance from the middle of one rarefaction to the middle of next one.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n- define the terms wavelength and frequency\u0026lt;br \/\u0026gt;\n- distinguish between transverse and longitudinal waves\u0026lt;br \/\u0026gt;\n- determine the wavelength and frequency of both the transverse and longitudinal waves","BACKING_FILE":"hs400063.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs400063","TOPIC_ID":"hs400063","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400063.jpg","PUBLIC_BANNER_IMG":"HS400063.jpg","PUBLIC_VIDEO":"pvideo_hs400063.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/M6evzqk7etg","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;The wavelength of a transverse wave is the distance from crest to crest or trough to trough. The wavelength of a longitudinal wave is the distance from the middle of one compression to the middle of the next one, or the distance from the middle of one rarefaction to the middle of another.\u0026amp;nbsp;Frequency is commonly measured in hertz (Hz).\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define the terms wavelength and frequency.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Distinguish between transverse and longitudinal waves.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Determine the wavelength and frequency of transverse and longitudinal waves.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Wavelength and Frequency","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"46","CATEGORY_ID":"1","CONT_TITLE":"Series and Parallel Circuits","CONT_SLUG":"series-and-parallel-circuits","CONT_TITLE_AR":"Series and Parallel Circuits","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThere are two basic ways in which more than two circuit components can be connected: series and parallel. A series circuit is an electric circuit with only one branch. The amount of current is the same through every part of the circuit. If any part is disconnected, no current runs through the circuit. Parallel circuits contain two or more branches for current. Devices on each branch can be turned on or off separately.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify circuits connected in series.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify circuits connected in parallel.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the behavior of current and voltage in series and parallel circuits.\u003C\/div\u003E","CONT_DESC_AR":"There are two basic ways in which to connect more than two circuit components: series and parallel. A series circuit is an electric circuit with only one branch. The amount of current is same through every part of a series circuit. If any part is disconnected, no current runs through the circuit. Parallel circuits contain two or more branches for current. Devices on each branch can be turned on or off separately.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n- identify circuits connected in series\u0026lt;br \/\u0026gt;\n- identify circuits connected in parallel\u0026lt;br \/\u0026gt;\n- know the behavior of current and voltage in series and parallel circuits","BACKING_FILE":"hs400034.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs400034","TOPIC_ID":"hs400034","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400034.jpg","PUBLIC_BANNER_IMG":"HS400034.jpg","PUBLIC_VIDEO":"pvideo_hs400034.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/q7TltIu5xEY","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;There are two basic ways in which more than two circuit components can be connected: series and parallel. A series circuit is an electric circuit with only one branch. The amount of current is the same through every part of the circuit. If any part is disconnected, no current runs through the circuit. Parallel circuits contain two or more branches for current. Devices on each branch can be turned on or off separately.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify circuits connected in series.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify circuits connected in parallel.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the behavior of current and voltage in series and parallel circuits.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Series and Parallel Circuits","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"STEM"},{"CONT_ID":"35","CATEGORY_ID":"1","CONT_TITLE":"Working of Electric Motor","CONT_SLUG":"working-of-electric-motor","CONT_TITLE_AR":"Working of Electric Motor","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIn a simple electric motor, an electromagnet rotates between the poles of a permanent magnet. Electric motor converts electrical energy to mechanical energy.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain that in a simple electric motor, an electromagnet rotates between the poles of a permanent magnet.\u003C\/div\u003E","CONT_DESC_AR":"In a simple electric motor, an electromagnet rotates between the poles of a permanent magnet.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objective:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to explain:\u0026lt;br \/\u0026gt;\n- in a simple electric motor, an electromagnet rotates between the poles of a permanent magnet","BACKING_FILE":"ms400015.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms400015","TOPIC_ID":"ms400015","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400015.jpg","PUBLIC_BANNER_IMG":"MS400015.jpg","PUBLIC_VIDEO":"pvideo_ms400015.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/owqWwjzXnBQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;In a simple electric motor, an electromagnet rotates between the poles of a permanent magnet. Electric motor converts electrical energy to mechanical energy.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objective\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain that in a simple electric motor, an electromagnet rotates between the poles of a permanent magnet.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Working of Electric Motor","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"32","CATEGORY_ID":"1","CONT_TITLE":"The Principle and Construction of an Electric Motor","CONT_SLUG":"principle-and-construction-of-electric-motor","CONT_TITLE_AR":"Principle and Construction of Electric Motor","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \u003C\/div\u003E \r\n\u003Cdiv\u003EAn electric motor is a device that converts electrical energy to mechanical energy. Electric motors are used in all types of industries, including agriculture and transportation. For example, electric motors are used in computers, DVD players, fans and hair dryers.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain what an electric motor is.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explore the uses of electric motors in different devices.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the working principle and construction of an electric motor.\u003C\/div\u003E","CONT_DESC_AR":"An electric motor is a device that converts electrical energy to mechanical energy. Electric motors are used in all types of industries, including agriculture and transportation. For example electric motors are used in computers, DVD players, fans and hair dryers.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\nIn this simulation, you will be aware that:\u0026lt;br \/\u0026gt;\n- an electric motor is a device that converts electrical energy into mechanical energy\u0026lt;br \/\u0026gt;\n-\u0026amp;nbsp;electric motors are used in all types of industry, agriculture and transportation. For example electric motors are used in computers, DVD players, fans and hair dryers","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs400007","TOPIC_ID":"hs400007","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400007.jpg","PUBLIC_BANNER_IMG":"HS400007.jpg","PUBLIC_VIDEO":"pvideo_hs400007.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/GtanWhepR6Y","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;An electric motor is a device that converts electrical energy to mechanical energy. Electric motors are used in all types of industries, including agriculture and transportation. For example, electric motors are used in computers, DVD players, fans and hair dryers.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain what an electric motor is.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explore the uses of electric motors in different devices.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the working principle and construction of an electric motor.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"The Principle and construction of an Electric Motor","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"16","CATEGORY_ID":"1","CONT_TITLE":"Electric Generator","CONT_SLUG":"electric-generator","CONT_TITLE_AR":"Electric Generator","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn electric generator converts mechanical energy into electric energy. It consists of four parts: armature, permanent magnet, slip rings and brushes. When the armature moves in a magnetic field of a permanent magnet, a current induces in the armature.\u003C\/div\u003E \r\n\u003Cdiv\u003E\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the construction of electric generator.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Demonstrate the working of electric generator.\u003C\/div\u003E","CONT_DESC_AR":"A coil moving within the magnetic field of a permanent magnet induces a current in the coil. The current in the coil changes direction each time the ends of the coil move past the poles of the permanent magnet.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\nIn this simulation, you will explain:\u0026lt;br \/\u0026gt;\n-\u0026amp;nbsp;movement of a coil in the magnetic field of the permanent magnet will induce a current in the coil\u0026lt;br \/\u0026gt;\n- the current in the coil changes direction each time the ends of the coil move past the poles of the permanent magnet","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms400028","TOPIC_ID":"ms400028","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400028.jpg","PUBLIC_BANNER_IMG":"MS400028.jpg","PUBLIC_VIDEO":"pvideo_ms400028.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/d7kIEL9fzHA","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-23 10:00:39","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;Overview:\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;An electric generator converts mechanical energy into electric energy. It consists of four parts: armature, permanent magnet, slip rings and brushes. When the armature moves in a magnetic field of a permanent magnet, a current induces in the armature.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;Learning Objectives:\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;After completing this module, you will be able to:\u0026amp;nbsp;\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;- Describe the construction of electric generator.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-family: Arial;\u0026quot;\u0026gt;- Demonstrate the working of electric generator.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Electric Generator","ADMSUBJECT_ID":"1342","ADMCOURSE_ID":"383","DISPLAY_NAME":"Physics","DISPLAY_NAME_AR":"","SUBJECT_NAME":"Physics","SUBJECT_NAME_AR":"","SUBJECT_DESC":"Description","SUBJECT_DESC_AR":"","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"Grade 12","COUNTRY_ID":"342","SHORT_NAME":"ICSE","DOMAIN_NAME":"Higher Education"}],"levelObject":["Refracting Telescope","Eyepiece","Objective Lens","Image","Object","Real Image","Inverted Image","Lens","Virtual Image","Magnified Image","Focal Length","Focal 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distant object.\u003C\/div\u003E","CONT_DESC_AR":"A refracting telescope uses lenses to gather the light from the distant objects.\u003C\/br\u003E\u003C\/br\u003E\r\nLearning Objectives:\u003C\/br\u003E\u003C\/br\u003E\r\nIn this simulation, you will be able to:\u003C\/br\u003E\r\n- state the use of a refracting telescope\u003C\/br\u003E\r\n- label the basic parts of a refracting telescope used in the formation of the image of a distant object\u003C\/br\u003E\r\n- trace the ray diagram used in the formation of the image of a distant 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