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The pressure exerted by air is called air pressure. The air in the atmosphere exerts pressure on every object and in all directions. Air movement can cause changes in air pressure.\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 that air in the atmosphere exerts pressure on every object and in all directions.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain that high wind speed causes reduced air pressure.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain why roofs, which are not firmly fixed, are blown off when a strong wind blows over them.\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.vp000001","TOPIC_ID":"vp000001","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_vp000001.jpg","PUBLIC_BANNER_IMG":"vp000001.jpg","PUBLIC_VIDEO":"en_us_pvideo_vp000001.mp4","PUBLIC_VIDEO_URL":null,"DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;Wind speed is closely related to air pressure. 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Air movement can cause changes in air pressure.\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;- State that air in the atmosphere exerts pressure on every object and in all directions.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain that high wind speed causes reduced air pressure.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain why roofs, which are not firmly fixed, are blown off when a strong wind blows over them.\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Wind Speed and Air Pressure","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"475","CATEGORY_ID":"1","CONT_TITLE":"Transferring Charge by Contact","CONT_SLUG":"transferring-charge-by-contact","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\u003ESome materials hold their electrons more loosely than other materials. When objects which are made of different materials come in contact with each other, electrons tend to collect on the object that holds the electrons more tightly. This is called transferring charge by contact. 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Both insulators and conductors can be charged by contact.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;After completing this module, you will be able to:\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Describe the transfer of charge through contact.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Explain that the transfer of electrons causes the transfer of charge when two objects come in contact.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Describe that charged objects attract uncharged objects.\u0026lt;\/span\u0026gt;\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Transferring Charge by Contact","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"471","CATEGORY_ID":"1","CONT_TITLE":"Bernoulli\u0027s Principle","CONT_SLUG":"bernoullis-principle","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\u003EBernoulli\u0026#039;s principle states that the pressure of a fluid decreases when the speed of that fluid 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- Describe why water moves faster in a squeezed part of a hose.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain how wind blows off the roof of a house in accordance with Bernoulli\u0026#039;s principle.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain how a soccer player makes use of Bernoulli\u0026#039;s principle to curve the ball.\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.ms400517","TOPIC_ID":"ms400517","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400517.jpg","PUBLIC_BANNER_IMG":"MS400517.jpg","PUBLIC_VIDEO":"pvideo_ms400517.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/WtSjA75B0TI","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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":"\u0026lt;p\u0026gt;Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Bernoulli\u0026#039;s principle states that the pressure of a fluid decreases when the speed of that fluid increases.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;After completing this module, you will be able to:\u0026amp;nbsp;\u0026lt;\/span\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Describe why water moves faster in a squeezed part of a hose.\u0026lt;\/span\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Explain how wind blows off the roof of a house in accordance with Bernoulli\u0026#039;s principle.\u0026lt;\/span\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Explain how a soccer player makes use of Bernoulli\u0026#039;s principle to curve the ball\u0026lt;\/span\u0026gt;.\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Bernoulli\u0027s Principle","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"460","CATEGORY_ID":"1","CONT_TITLE":"Electric Forces","CONT_SLUG":"electric-forces","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\u003EA force acting between charged objects, even when they are not in contact with each other, is known as an electric force.\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 electric forces.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Illustrate the electric forces between similar electric charges and opposite electric charges.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the factors affecting the electric forces between two charged objects.\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.ms400385","TOPIC_ID":"ms400385","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400385.jpg","PUBLIC_BANNER_IMG":"MS400385.jpg","PUBLIC_VIDEO":"pvideo_ms400385.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/XNafqEXwkAw","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;A force acting between charged objects, even when they are not in contact with each other, is known as an electric force.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;- Define electric forces.\u0026lt;br\u0026gt;- Illustrate the electric forces between similar electric charges and opposite electric charges.\u0026lt;br\u0026gt;- Explain the factors affecting the electric forces between two charged objects.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Electric Forces","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"457","CATEGORY_ID":"1","CONT_TITLE":"Density of Fluids","CONT_SLUG":"density-of-fluids","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\u003EDensity of a fluid is defined as the ratio of mass and volume of the fluid. If the density of an object is greater than that of the fluid, then the object will sink. If the density of the object is smaller than that of the fluid, then the object will float. If the density of the object is equal to that of the fluid, then the object will neither float nor sink. The pressure variation that is observed in different fluids is due to density. \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 pressure due to fluids at different depths and altitudes.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Compare densities of different materials.\u003C\/div\u003E\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.ms400286","TOPIC_ID":"ms400286","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400286.jpg","PUBLIC_BANNER_IMG":"MS400286.jpg","PUBLIC_VIDEO":"pvideo_ms400286.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/7mNuLvkg21k","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;Density of a fluid is defined as the ratio of mass and volume of the fluid. If the density of an object is greater than that of the fluid, then the object will sink. If the density of the object is smaller than that of the fluid, then the object will float. If the density of the object is equal to that of the fluid, then the object will neither float nor sink. The pressure variation that is observed in different fluids is due to density.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026amp;nbsp;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;\u0026amp;nbsp;- Compare the pressure due to fluids at different depths and altitudes.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Compare densities of different materials.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Density of Fluids","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"451","CATEGORY_ID":"1","CONT_TITLE":"Earth\u0027s Magnetic Field","CONT_SLUG":"earths-magnetic-field","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\u003EEarth acts as a magnet. It has a north magnetic pole and a south magnetic pole. Earth\u0026#039;s magnetic field extends from the Earth\u0026#039;s interior out into space.\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 existence of a magnetic field around Earth.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the importance of Earth\u0026#039;s magnetic field.\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.ms400170","TOPIC_ID":"ms400170","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400170.jpg","PUBLIC_BANNER_IMG":"MS400170.jpg","PUBLIC_VIDEO":"pvideo_ms400170.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/T6mzqK7Ibws","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;Earth acts as a magnet. It has a north magnetic pole and a south magnetic pole. Earth\u0026#039;s magnetic field extends from the Earth\u0026#039;s interior out into space.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the existence of a magnetic field around Earth.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the importance of Earth\u0026#039;s 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":"Earth\u0027s Magnetic Field","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","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":"2019-07-25 08:37:46","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":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"448","CATEGORY_ID":"1","CONT_TITLE":"Newton\u2019s Second Law of Motion","CONT_SLUG":"newton\u2019s-second-law-of-motion","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E\r\n \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E\r\n \r\n\u003Cdiv\u003ENewton\u0026#039;s second law of motion pertains to the behavior of objects for which all existing forces are not balanced. The second law states that the acceleration of an object is dependent upon two variables - the net force acting upon the object and the mass of the object. The acceleration of an object depends directly upon the net force acting upon the object, and inversely upon the mass of the object. As the force acting upon an object is increased, the acceleration of the object is increased. As the mass of an object is increased, the acceleration of the object is decreased.\u003C\/div\u003E\r\n \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E\r\n \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E\r\n \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E\r\n \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E\r\n \r\n\u003Cdiv\u003E- Explain Newton\u0026#039;s second law of motion.\u003C\/div\u003E\r\n \r\n\u003Cdiv\u003E- Explore the relationship between force and mass.\u003C\/div\u003E\r\n \r\n\u003Cdiv\u003E- Explore the relationship between force and acceleration.\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.hs400127","TOPIC_ID":"hs400127","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400127.jpg","PUBLIC_BANNER_IMG":"HS400127.jpg","PUBLIC_VIDEO":"pvideo_hs400127.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/FCY3qLbfvAY","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;Newton\u0026#039;s second law of motion pertains to the behavior of objects for which all existing forces are not balanced. The second law states that the acceleration of an object is dependent upon two variables - the net force acting upon the object and the mass of the object. The acceleration of an object depends directly upon the net force acting upon the object, and inversely upon the mass of the object. As the force acting upon an object is increased, the acceleration of the object is increased. As the mass of an object is increased, the acceleration of the object is decreased.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;- Explain Newton\u0026#039;s second law of motion.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explore the relationship between force and mass.\u0026lt;\/div\u0026gt;- Explore the relationship between force and acceleration.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Newton\u0027s Second Law of Motion","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"447","CATEGORY_ID":"1","CONT_TITLE":"Newton\u0027s First Law of Motion","CONT_SLUG":"newtons-first-law-of-motion","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\u003ENewton\u2019s first law deals with objects at rest or those moving at constant speed. Newton stated that if the resultant force on an object is zero then an object at rest will remain at rest and an object in motion will continue its motion in the same direction at constant speed. This means that all objects have a natural tendency to keep on doing what they are doing. All objects have a reluctance to change their state of motion and require an unbalanced force to bring about a change. The reluctance or resistance of a mass to change its state of motion is referred to as inertia.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E\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 Newton\u0026#039;s first law of motion.\u003C\/div\u003E \r\n\u003Cdiv\u003E- List the applications of Newton\u0026#039;s first law of motion.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Relate balanced forces and the motion of a body.\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.hs400126","TOPIC_ID":"hs400126","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400126.jpg","PUBLIC_BANNER_IMG":"HS400126.jpg","PUBLIC_VIDEO":"pvideo_hs400126.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/g_J5ZDuaeBQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;Newton\u2019s first law deals with objects at rest or those moving at constant speed. Newton stated that if the resultant force on an object is zero then an object at rest will remain at rest and an object in motion will continue its motion in the same direction at constant speed. This means that all objects have a natural tendency to keep on doing what they are doing. All objects have a reluctance to change their state of motion and require an unbalanced force to bring about a change. The reluctance or resistance of a mass to change its state of motion is referred to as inertia.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;After completing this module, you will be able to:\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Explain Newton\u0026#039;s first law of motion.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- List the applications of Newton\u0026#039;s first law of motion.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Relate balanced forces and the motion of a body\u0026lt;\/span\u0026gt;.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Newton\u0027s First Law of Motion","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"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. Each domain is a tiny magnet with a north pole and a south pole.\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- describe magnetic domains\u0026lt;br \/\u0026gt;\n- demonstrate the behavior of magnetic domains in different magnetic materials\u0026lt;\/p\u0026gt;\n","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.ms400067","TOPIC_ID":"ms400067","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400067.jpg","PUBLIC_BANNER_IMG":"MS400067.jpg","PUBLIC_VIDEO":"pvideo_ms400067.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/PJpTwS6V93Q","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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 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.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\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;In this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe magnetic domains.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Demonstrate the behavior of magnetic domains in different magnetic materials.\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":"Magnetic Domain","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"337","CATEGORY_ID":"1","CONT_TITLE":"Pascal\u0027s Principle and Hydraulic Pressure","CONT_SLUG":"pascals-principle-and-hydraulic-pressure","CONT_TITLE_AR":"Pascals Principle and Hydraulic Pressure","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIn fluid mechanics, Pascal\u2019s principle describes that in a confined incompressible fluid a pressure change is transmitted throughout the fluid, such that same change occurs everywhere.\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- Demonstrate that the pressure on an enclosed fluid is transmitted undiminished to every part of the fluid.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Illustrate the application of Pascal\u0026#039;s principle in a hydraulic lift used to raise a car off the ground.\u003C\/div\u003E","CONT_DESC_AR":"Pressure applied to a fluid is transmitted through the fluid and can be written as pressure in = pressure out.\u003C\/br\u003E\u003C\/br\u003E\r\n\u003Cstrong\u003ELearning Objective:\u003C\/strong\u003E\u003C\/br\u003E\u003C\/br\u003E\r\nIn this simulation, you will become aware that\u003C\/br\u003E\r\n1.pressure applied to a fluid is transmitted through the fluid and can be written as: pressure in = pressure out","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.ss400032","TOPIC_ID":"ss400032","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400032.jpg","PUBLIC_BANNER_IMG":"SS400032.jpg","PUBLIC_VIDEO":"pvideo_ss400032.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/jRsM3xTFe2w","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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 fluid mechanics, Pascal\u2019s principle describes that in a confined incompressible fluid a pressure change is transmitted throughout the fluid, such that same change occurs everywhere.\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;- Demonstrate that the pressure on an enclosed fluid is transmitted undiminished to every part of the fluid.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Illustrate the application of Pascal\u0026#039;s principle in a hydraulic lift used to raise a car off the ground.\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":"Pascal\u0027s Principle and Hydraulic Pressure","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"144","CATEGORY_ID":"1","CONT_TITLE":"Electron Distribution in Different Shells","CONT_SLUG":"electron-distribution-in-different-shells","CONT_TITLE_AR":"Electron Distribution in Different Shells","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EElectrons are arranged in energy levels, or shells, around the nucleus of an atom. The shell nearest to the nucleus has the least energy and subsequent shells have progressively more energy. Electrons first occupy lowest-energy shell, subsequent shells are occupied according to increasing order of energy. The maximum number of electrons that can be accommodated in any energy level is given by 2n\u00b2 where n is the number of the energy level, such as 1, 2, 3, 4...\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 rules for filling electrons in different atomic shells.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Arrange electrons in different atomic shells up to first 20 elements.\u003C\/div\u003E","CONT_DESC_AR":"Electrons are arranged in energy levels, or shells, around the nucleus of an atom. The shell nearest the nucleus has the least energy and subsequent shells have progressively more energy. The electron first occupy the lowest-energy shell, subsequent shells are occupied according to increasing order of energy. The maximum number of electrons that can be accommodated in any energy level is given by 2n2 where n is the number of the energy level, such as 1, 2, 3, 4...\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning objectives\u0026amp;nbsp;\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the rules for filling different atomic shells with electrons\u0026lt;br \/\u0026gt;\n\u0026amp;bull; arrange electrons in different atomic shells for the first 20 elements","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.hs200004","TOPIC_ID":"hs200004","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200004.jpg","PUBLIC_BANNER_IMG":"HS200004.jpg","PUBLIC_VIDEO":"pvideo_hs200004.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/rzCLxuiGR_A","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;\u0026lt;div\u0026gt;Electrons are arranged in energy levels, or shells, around the nucleus of an atom. The shell nearest to the nucleus has the least energy and subsequent shells have progressively more energy. Electrons first occupy lowest-energy shell, subsequent shells are occupied according to increasing order of energy. The maximum number of electrons that can be accommodated in any energy level is given by 2n\u00b2 where n is the number of the energy level, such as 1, 2, 3, 4...\u0026lt;\/div\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;- Explain the rules for filling electrons in different atomic shells.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Arrange electrons in different atomic shells up to first 20 elements.\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":"Electron Distribution in Different Shells","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"116","CATEGORY_ID":"1","CONT_TITLE":"Floatation and Immersion of a Body","CONT_SLUG":"floatation-and-immersion-of-a-body","CONT_TITLE_AR":"Floatation and Immersion of a Body","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn object can float or sink depending on its density as compared to the density of the fluid in which it is placed. An object floats if its density is less than that of the fluid. An object sinks if its density is more than that of the fluid.\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 the conditions required for an object to float or sink in a liquid.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Demonstrate the floating or sinking of different objects in different liquids.\u003C\/div\u003E","CONT_DESC_AR":"An object can float or sink depending on its density as compared to the density of the fluid in which it is placed. An object floats if its density is less than that of the fluid. An object sinks if its density is more than that of the fluid.\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- identify the conditions required for an object to float or sink in a liquid\u0026lt;br \/\u0026gt;\n- demonstrate the floating or sinking of different objects in different liquids","BACKING_FILE":"ss400045.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss400045","TOPIC_ID":"ss400045","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400045.jpg","PUBLIC_BANNER_IMG":"SS400045.jpg","PUBLIC_VIDEO":"pvideo_ss400045.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/gG7MYl_Tz5g","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;p\u0026gt;Overview:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;An object can float or sink depending on its density as compared to the density of the fluid in which it is placed. An object floats if its density is less than that of the fluid. An object sinks if its density is more than that of the fluid.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;Learning Objectives:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;After completing this module, you will be able to:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Identify the conditions required for an object to float or sink in a liquid.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Demonstrate the floating or sinking of different objects in different liquids.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Floatation and Immersion of a body","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"88","CATEGORY_ID":"1","CONT_TITLE":"Transformers","CONT_SLUG":"transformer","CONT_TITLE_AR":"Transformer","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA transformer is a device that increases or decreases the voltage of an alternating current. The transfer which increases the voltage is called a step-up transformer. The transfer which decreases the voltage is called a step-down transformer.\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 what is transformer.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explore the basic parts of transformer.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explore the types of transformer.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Differentiate between the types of transformer.\u003C\/div\u003E","CONT_DESC_AR":"A transformer is a device that increases or decreases the voltage of an alternating current.\u003C\/br\u003E\u003C\/br\u003E\r\n\u003Cstrong\u003ELearning Objective:\u003C\/strong\u003E\u003C\/br\u003E\u003C\/br\u003E\r\nIn this simulation, you will be able to:\u003C\/br\u003E\r\n- explain that a transformer is a device that increases or decreases the voltage of an alternating current","BACKING_FILE":"ss400038.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss400038","TOPIC_ID":"ss400038","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS400038.jpg","PUBLIC_BANNER_IMG":"SS400038.jpg","PUBLIC_VIDEO":"pvideo_ss400038.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/qEK91CjDYuQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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 transformer is a device that increases or decreases the voltage of an alternating current. The transfer which increases the voltage is called a step-up transformer. The transfer which decreases the voltage is called a step-down transformer.\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 what is transformer.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explore the basic parts of transformer.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explore the types of transformer.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Differentiate between the types of transformer.\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":"Transformer","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","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":"2019-07-25 08:37:46","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":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"53","CATEGORY_ID":"1","CONT_TITLE":"Electroscope","CONT_SLUG":"electroscope","CONT_TITLE_AR":"Electroscope","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn electroscope is a device to detect the presence of electric charge in an object. When an object is brought into contact with the metal knob of an uncharged electroscope, the divergence of the device\u0026#039;s metal leaves indicates the presence of electric charge in the object.\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 construction of a simple electroscope.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Examine the working of an uncharged electroscope when a charged object is brought in contact with it.\u003C\/div\u003E","CONT_DESC_AR":"An electroscope is a device to detect the presence of electric charge in an object. When an object is brought into contact with the metal knob of an uncharged electroscope, the divergence of leaves indicates the presence of electric charge in the object.\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-\u0026amp;nbsp;describe the construction of a simple electroscope\u0026lt;br \/\u0026gt;\n- examine the working of an uncharged electroscope when a charged object is brought in contact with it","BACKING_FILE":"hs400047.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs400047","TOPIC_ID":"hs400047","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400047.jpg","PUBLIC_BANNER_IMG":"HS400047.jpg","PUBLIC_VIDEO":"pvideo_hs400047.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/lo6dum3RX7k","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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 electroscope is a device to detect the presence of electric charge in an object. When an object is brought into contact with the metal knob of an uncharged electroscope, the divergence of the device\u0026#039;s metal leaves indicates the presence of electric charge in the object.\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 construction of a simple electroscope.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Examine the working of an uncharged electroscope when a charged object is brought in contact with it.\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":"Electroscope","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"50","CATEGORY_ID":"1","CONT_TITLE":"Archimedes\u0027 Principle","CONT_SLUG":"archimedes-principle","CONT_TITLE_AR":"Archimede\u0027s Principle","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn object experiences an upward force called buoyant force when immersed in a fluid. This upward force opposes the weight of the object, resulting in a decrease of its weight. Archimedes\u2019 principle states that when a object is partially or fully immersed in a liquid, it experiences an upward thrust (buoyant force) which is equal to the weight of the fluid displaced by the immersed part of the object.\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 buoyant force.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define Archimedes\u0026#039; principle.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Demonstrate Archimedes\u0026#039; principle.\u003C\/div\u003E","CONT_DESC_AR":"An object experiences an upward force called buoyant force when immersed in a fluid. This upward force opposes the weight of the object, resulting in a decrease of its weight. Archimedes\u0026amp;rsquo; principle states that when a body is partially or fully immersed in a liquid, it experiences an upward thrust (buoyant force) which is equal to the weight of the fluid displaced by the immersed part of the body.\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 buoyant force\u0026lt;br \/\u0026gt;\n- define Archimedes\u0026amp;#39; principle\u0026lt;br \/\u0026gt;\n- demonstrate Archimedes\u0026amp;#39; principle","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.hs400009","TOPIC_ID":"hs400009","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400009.jpg","PUBLIC_BANNER_IMG":"HS400009.jpg","PUBLIC_VIDEO":"pvideo_hs400009.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/hyU3OgPoZpg","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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 object experiences an upward force called buoyant force when immersed in a fluid. This upward force opposes the weight of the object, resulting in a decrease of its weight. Archimedes\u2019 principle states that when a object is partially or fully immersed in a liquid, it experiences an upward thrust (buoyant force) which is equal to the weight of the fluid displaced by the immersed part of the object.\u0026amp;nbsp;\u0026amp;nbsp;\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 buoyant force.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define Archimedes\u0026#039; principle.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Demonstrate Archimedes\u0026#039; principle.\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":"Archimedes Principle","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"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":"2019-07-25 08:37:46","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":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"44","CATEGORY_ID":"1","CONT_TITLE":"Electric Charge","CONT_SLUG":"electric-charge","CONT_TITLE_AR":"Electric Charge","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EElectric charge is the physical property of matter that causes it to experience a force when placed in an electric field. There are two types of charges, positive and negative. Like charges repel each other and unlike charges attract each other.\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 why you receive a shock when you touch a metal door knob after walking across a carpet on a dry day.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe that the shock is the result of an electric charge.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Distinguish between the two types of charge: positive and negative.\u003C\/div\u003E","CONT_DESC_AR":"You might have gotten a shock when you touched a metal door knob. This experience is the result of electric charge. There are two types of charges, positive and negative.\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- explain why you receive a shock when you touch a metal door knob\u0026lt;br \/\u0026gt;\n- describe that the shock is the result of electric charge\u0026lt;br \/\u0026gt;\n- distinguish between the two types of charge: positive and negative","BACKING_FILE":"hs400031.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs400031","TOPIC_ID":"hs400031","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400031.jpg","PUBLIC_BANNER_IMG":"HS400031.jpg","PUBLIC_VIDEO":"pvideo_hs400031.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/kztJFuDsCtE","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;Electric charge is the physical property of matter that causes it to experience a force when placed in an electric field. There are two types of charges, positive and negative. Like charges repel each other and unlike charges attract each other.\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 why you receive a shock when you touch a metal door knob after walking across a carpet on a dry day.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe that the shock is the result of an electric charge.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Distinguish between the two types of charge: positive and negative.\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":"Electric Charge","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"37","CATEGORY_ID":"1","CONT_TITLE":"Electromagnet","CONT_SLUG":"electromagnet","CONT_TITLE_AR":"Electromagnet","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn electromagnet is a temporary magnet created when there is a current flowing in a coiled wire. The strength of electromagnet depends upon the magnitude of current flowing through it.\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 construction of electromagnet.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Demonstrate the working of electromagnet.\u003C\/div\u003E","CONT_DESC_AR":"An electromagnet is a temporary magnet created when there is a current flowing in a coiled wire.\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:\u0026lt;br \/\u0026gt;\n- explain that the electromagnet is a temporary magnet created when there is a current in a coiled wire","BACKING_FILE":"hs400014.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs400014","TOPIC_ID":"hs400014","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400014.jpg","PUBLIC_BANNER_IMG":"HS400014.jpg","PUBLIC_VIDEO":"pvideo_hs400014.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/_stHgbgw7S4","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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 electromagnet is a temporary magnet created when there is a current flowing in a coiled wire. The strength of electromagnet depends upon the magnitude of current flowing through it.\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 construction of electromagnet.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Demonstrate the working of electromagnet.\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":"Electromagnet","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"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":"2019-07-25 08:37:46","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":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","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":"2019-07-25 08:37:46","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":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"31","CATEGORY_ID":"1","CONT_TITLE":"Poles of a Magnet","CONT_SLUG":"poles-of-a-magnet","CONT_TITLE_AR":"Poles of a Magnet","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003EMagnet ends, where the force applied by the magnet is the strongest, are called the poles of the magnets. There are two magnetic poles - north pole and south pole. If the opposite poles or unlike poles (north pole and south pole) of two magnets are brought together, the magnets are attracted to each other. If similar poles or like poles face each other (north\/north or south\/south), the magnets repel each other. \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 the poles of a magnet.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Relate the magnetic poles of a magnet to the Earth\u0026#039;s geographic North Pole and South Pole.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explore the force between opposite poles of a magnet.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explore the force between similar poles of a magnet.\u003C\/div\u003E","CONT_DESC_AR":"Magnet ends, where the force applied by the magnet is the strongest, are called the poles of the magnets. There are two magnetic poles - north pole and south pole. If the opposite poles or unlike poles (north pole and south pole) of two magnets are brought together, the magnets are attracted to each other. If similar poles or like poles face each other (north\/north or south\/south), the magnets repel each other.\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 the poles of a magnet\u0026lt;br \/\u0026gt;\n- relate the magnetic poles of the magnet to the Earth\u0026amp;#39;s geographic north and south pole\u0026lt;br \/\u0026gt;\n- explore the force between opposite poles of a magnet\u0026lt;br \/\u0026gt;\n- explore the force between similar poles of a 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.ms400026","TOPIC_ID":"ms400026","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS400026.jpg","PUBLIC_BANNER_IMG":"MS400026.jpg","PUBLIC_VIDEO":"pvideo_ms400026.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/-33p2UXW4Ho","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"6","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;Magnet ends, where the force applied by the magnet is the strongest, are called the poles of the magnets. There are two magnetic poles - north pole and south pole. If the opposite poles or unlike poles (north pole and south pole) of two magnets are brought together, the magnets are attracted to each other. If similar poles or like poles face each other (north\/north or south\/south), the magnets repel each other.\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;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the poles of a magnet.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Relate the magnetic poles of a magnet to the Earth\u0026#039;s geographic North Pole and South Pole.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explore the force between opposite poles of a magnet.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explore the force between similar poles of a magnet.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Poles of a magnet","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"},{"CONT_ID":"30","CATEGORY_ID":"1","CONT_TITLE":"Electric Current and Voltage Difference","CONT_SLUG":"electric-current-and-voltage-difference","CONT_TITLE_AR":"Electric Current and Voltage Difference","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe flow of charges, in a single direction, is called electric current. The unit of electric current is ampere (A). Ammeter is the instrument which is used to measure the current. The direction of current is from higher voltage to lower voltage. The difference of voltage is measured in volts (V). Voltmeter is the instrument which is used to measure voltage differences.\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 different components of an electric circuit such as the power supply, battery, ammeter, voltmeter, electric lamp, and electric switch.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the two terminals of a battery, the direction of the current, and the electron flow.\u003C\/div\u003E","CONT_DESC_AR":"The flow of charges, in a single direction, is called electric current. The Unit of current is ampere. 1 A = 1 C\/1 s. An Ammeter is the instrument used to measure current. The direction of current is from higher to lower voltage. The difference is measured in volts (V). A voltmeter is the instrument used to measure voltage differences. For electric charges to flow, we need a continuous path called an electric circuit.\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 different components of an electric circuit\u0026lt;br \/\u0026gt;\n- identify the terminals of a battery, and the direction of current and electron flow","BACKING_FILE":"hs400006.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs400006","TOPIC_ID":"hs400006","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400006.jpg","PUBLIC_BANNER_IMG":"HS400006.jpg","PUBLIC_VIDEO":"pvideo_hs400006.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/eD32tM0Jl1A","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;h3\u0026gt;Overview:\u0026lt;\/h3\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;The flow of charges, in a single direction, is called electric current. The unit of electric current is ampere (A). Ammeter is the instrument which is used to measure the current. The direction of current is from higher voltage to lower voltage. The difference of voltage is measured in volts (V). Voltmeter is the instrument which is used to measure voltage differences.\u0026amp;nbsp;\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;h3\u0026gt;Learning Objectives:\u0026lt;\/h3\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the different components of an electric circuit such as the power supply, battery, ammeter, voltmeter, electric lamp, and electric switch.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the two terminals of a battery, the direction of the current, and the electron flow.\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Electric current and Voltage difference","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"CONT_ID":"27","CATEGORY_ID":"1","CONT_TITLE":"Ohm\u0027s Law","CONT_SLUG":"ohms-law","CONT_TITLE_AR":"Ohm\u0027s Law","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \u003C\/div\u003E \r\n\u003Cdiv\u003EOhm\u0026#039;s Law describes the relationship between voltage and current in an ideal conductor. This relationship states that the potential difference or voltage across an ideal conductor is directly proportional to the current flowing through it.\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 if temperature and material of a substance remain unchanged, then the current through a conductor is directly proportional to the voltage difference across it.\u003C\/div\u003E \r\n\u003Cdiv\u003E- For an Ohmic conductor, the voltage to current plot is always a straight line.\u003C\/div\u003E \r\n\u003Cdiv\u003E- The Voltage to Current, or V\/I, ratio is constant and gives the measurement of resistance.\u003C\/div\u003E","CONT_DESC_AR":"Ohms Law describes the relationship between voltage and current in an ideal conductor. This relationship states that the potential difference (voltage) across an ideal conductor is proportional to the current flowing through it.\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 learn:\u0026lt;br \/\u0026gt;\n- if temperature and material of a substance remains unchanged then the current through a conductor is directly proportional the voltage difference across it\u0026lt;br \/\u0026gt;\n- for an Ohmic conductor, the V\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n- I plot is always a straight line\u0026lt;br \/\u0026gt;\n- the V\/I ratio is constant and gives the measurement of resistance","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.hs400005","TOPIC_ID":"hs400005","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS400005.jpg","PUBLIC_BANNER_IMG":"HS400005.jpg","PUBLIC_VIDEO":"pvideo_hs400005.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/EU4L1QVHfuU","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2019-07-25 08:37:46","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;h3\u0026gt;Overview:\u0026lt;\/h3\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Ohm\u0026#039;s Law describes the relationship between voltage and current in an ideal conductor. This relationship states that the potential difference or voltage across an ideal conductor is directly proportional to the current flowing through it.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;h3\u0026gt;Learning Objectives:\u0026lt;\/h3\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 if temperature and material of a substance remain unchanged, then the current through a conductor is directly proportional to the voltage difference across it.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- For an Ohmic conductor, the voltage to current plot is always a straight line.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- The Voltage to Current, or V\/I, ratio is constant and gives the measurement of resistance.\u0026lt;br\u0026gt;\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":"Ohm\u0027s Law","ADMSUBJECT_ID":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"STEM"},{"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":"2019-07-25 08:37:46","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":"1351","ADMCOURSE_ID":"388","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":"Form 5","COUNTRY_ID":"343","SHORT_NAME":"Malaysia (KSSM) - Updated","DOMAIN_NAME":"Higher Education"}],"levelObject":["Air Pressure"],"contData":{"CONT_ID":"706","CATEGORY_ID":"1","CONT_TITLE":"Wind Speed and Air Pressure","CONT_SLUG":"wind-speed-and-air-pressure","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\u003EWind speed is closely related to air pressure. The pressure exerted by air is called air pressure. The air in the atmosphere exerts pressure on every object and in all directions. Air movement can cause changes in air pressure.\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 that air in the atmosphere exerts pressure on every object and in all directions.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain that high wind speed causes reduced air pressure.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain why roofs, which are not firmly fixed, are blown off when a strong wind blows over them.\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.vp000001","TOPIC_ID":"vp000001","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_vp000001.jpg","PUBLIC_BANNER_IMG":"vp000001.jpg","PUBLIC_VIDEO":"en_us_pvideo_vp000001.mp4","PUBLIC_VIDEO_URL":null,"DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-07-09 07:26:06","CREATED_BY":"2143","UPDATED_ON":"2024-10-07 12:12:17","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;Wind speed is closely related to air pressure. The pressure exerted by air is called air pressure. The air in the atmosphere exerts pressure on every object and in all directions. Air movement can cause changes in air pressure.\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;- State that air in the atmosphere exerts pressure on every object and in all directions.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain that high wind speed causes reduced air pressure.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain why roofs, which are not firmly fixed, are blown off when a strong wind blows over them.\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Wind Speed and Air Pressure","DISPLAY_NAME":"CBSE - Grade 7 - Science","DISPLAY_NAME_AR":"CBSE - Grade 7 - Science","SUBJECT_IMG":"562.jpg","ADMSUBJECT_ID":"562","SUBJECT_NAME":"Science","SUBJECT_NAME_AR":"Science","ADMCOURSE_ID":"194","COURSE_NAME":"Grade 7","COUNTRY_ID":"288","STANDARD_ID":"288","SHORT_NAME":"CBSE","LANG_ID":null,"LOCALE_TITLE":null,"LOCALE_DESC":null,"DIR":null,"LANG_NAME":null,"DOMAIN_NAME":"STEM","DOMAIN_DESC":"STEM"},"checkLang":["English - US","\u0639\u0631\u0628\u064a","Espa\u00f1ol","Ti\u1ebfng Vi\u1ec7t","\ud55c\uad6d\uc5b4"],"devices":["UmetyVR","WebXR"]}