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Finally, assume that after the object hits the ground it remains at h=0.\u003c/p\u003e","function_template":"function h = height_of_object_at_time(t)\r\n  h = t;\r\nend","test_suite":"%%\r\nt = -1;\r\nh_correct = 1000;\r\nassert(abs(height_of_object_at_time(t)-h_correct)\u003c0.1)\r\n%%\r\nt = 0;\r\nh_correct = 1000;\r\nassert(abs(height_of_object_at_time(t)-h_correct)\u003c0.1)\r\n%%\r\nt = 1;\r\nh_correct = 995.1;\r\nassert(abs(height_of_object_at_time(t)-h_correct)\u003c0.1)\r\n%%\r\nt = 10;\r\nh_correct = 510;\r\nassert(abs(height_of_object_at_time(t)-h_correct)\u003c0.1)\r\n%%\r\nt = 15;\r\nh_correct = 0;\r\nassert(abs(height_of_object_at_time(t)-h_correct)\u003c0.1)\r\n","published":true,"deleted":false,"likes_count":7,"comments_count":2,"created_by":9156,"edited_by":null,"edited_at":null,"deleted_by":null,"deleted_at":null,"solvers_count":323,"test_suite_updated_at":null,"rescore_all_solutions":false,"group_id":1,"created_at":"2012-12-12T04:04:57.000Z","updated_at":"2026-05-26T22:06:04.000Z","published_at":"2012-12-12T04:04:57.000Z","restored_at":null,"restored_by":null,"spam":false,"simulink":false,"admin_reviewed":false,"description_opc":"{\"relationships\":[{\"relationshipType\":\"http://schemas.mathworks.com/matlab/code/2013/relationships/document\",\"relationshipId\":\"rId1\",\"target\":\"/matlab/document.xml\"},{\"relationshipType\":\"http://schemas.mathworks.com/matlab/code/2013/relationships/output\",\"relationshipId\":\"rId2\",\"target\":\"/matlab/output.xml\"}],\"parts\":[{\"partUri\":\"/matlab/document.xml\",\"relationship\":[],\"contentType\":\"application/vnd.mathworks.matlab.code.document+xml\",\"content\":\"\u003c?xml version=\\\"1.0\\\" encoding=\\\"UTF-8\\\"?\u003e\u003cw:document xmlns:w=\\\"http://schemas.openxmlformats.org/wordprocessingml/2006/main\\\"\u003e\u003cw:body\u003e\u003cw:p\u003e\u003cw:pPr\u003e\u003cw:pStyle w:val=\\\"text\\\"/\u003e\u003c/w:pPr\u003e\u003cw:r\u003e\u003cw:t\u003eAssume that an object is dropped from 1000 meters above the surface of the earth at time t=0. The object is dropped such that the initial velocity and acceleration are both zero.\u003c/w:t\u003e\u003c/w:r\u003e\u003c/w:p\u003e\u003cw:p\u003e\u003cw:pPr\u003e\u003cw:pStyle w:val=\\\"text\\\"/\u003e\u003cw:jc w:val=\\\"left\\\"/\u003e\u003c/w:pPr\u003e\u003cw:r\u003e\u003cw:t\u003eWrite a function to determine the height, h, of the object at any time, t, where h=0 is the surface of the earth. Assume the acceleration due to gravity is constant 9.8 m/s^2. Also, assume that before the object is dropped (negative t) it is being held at a constant height of 1000 meters. 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