// Numbas version: exam_results_page_options {"name": "UWESbeMeCC2 Q2 - Friction on an Incline Plane - Randomised Variables Only", "extensions": [], "custom_part_types": [], "resources": [["question-resources/UWESbeMeCC1_-_Q2_Friction_on_a_Slope.jpg", "/srv/numbas/media/question-resources/UWESbeMeCC1_-_Q2_Friction_on_a_Slope.jpg"], ["question-resources/UWESbeMeCC1_-_Q2_Crate_A_FBD.png", "/srv/numbas/media/question-resources/UWESbeMeCC1_-_Q2_Crate_A_FBD.png"], ["question-resources/UWESbeMeCC1_-_Q2_Crate_A_B_FBD.png", "/srv/numbas/media/question-resources/UWESbeMeCC1_-_Q2_Crate_A_B_FBD.png"]], "navigation": {"allowregen": true, "showfrontpage": false, "preventleave": false, "typeendtoleave": false}, "question_groups": [{"pickingStrategy": "all-ordered", "questions": [{"name": "UWESbeMeCC2 Q2 - Friction on an Incline Plane - Randomised Variables Only", "tags": [], "metadata": {"description": "

2 bodies on an incline plane

Two blocks, A & B, rest on a slope at an angle of incline θ.

$\"2$

The mass and coefficents of friction between the crates and the plane are:

\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n

	mass (kg)	Coefficient of Friction (μ)
Crate A	{mass_crate_A}	{co_eff_A}
Crate B	{mass_crate_B}	{co_eff_B}

", "advice": "

Worked answers to follow exam

", "rulesets": {}, "extensions": [], "builtin_constants": {"e": true, "pi,\u03c0": true, "i": true}, "constants": [], "variables": {"Acc_Grav": {"name": "Acc_Grav", "group": "Ungrouped variables", "definition": "9.81", "description": "

Gravitational Constant

", "templateType": "number", "can_override": false}, "mass_crate_A": {"name": "mass_crate_A", "group": "Ungrouped variables", "definition": "random(30 .. 40#1)", "description": "", "templateType": "randrange", "can_override": false}, "mass_crate_B": {"name": "mass_crate_B", "group": "Ungrouped variables", "definition": "random(19 .. 25#1)", "description": "

Mass of Crate B (kg)

", "templateType": "randrange", "can_override": false}, "co_eff_A": {"name": "co_eff_A", "group": "Ungrouped variables", "definition": "random(0.15 .. 0.2#0.01)", "description": "", "templateType": "randrange", "can_override": false}, "Co_eff_B": {"name": "Co_eff_B", "group": "Ungrouped variables", "definition": "random(0.25 .. 0.32#0.01)", "description": "", "templateType": "randrange", "can_override": false}, "Theta_A": {"name": "Theta_A", "group": "Ungrouped variables", "definition": "degrees(arctan(co_eff_a))", "description": "", "templateType": "anything", "can_override": false}, "Theta_B": {"name": "Theta_B", "group": "Ungrouped variables", "definition": "degrees(arctan(co_eff_b))", "description": "", "templateType": "anything", "can_override": false}, "Weight_Crate_A": {"name": "Weight_Crate_A", "group": "Ungrouped variables", "definition": "mass_crate_a*acc_grav", "description": "

", "templateType": "anything", "can_override": false}, "Weight_Crate_B": {"name": "Weight_Crate_B", "group": "Ungrouped variables", "definition": "mass_crate_b*acc_grav", "description": "

", "templateType": "anything", "can_override": false}, "fric_A": {"name": "fric_A", "group": "Ungrouped variables", "definition": "weight_crate_a*co_eff_a", "description": "", "templateType": "anything", "can_override": false}, "fric_b": {"name": "fric_b", "group": "Ungrouped variables", "definition": "co_eff_b*weight_crate_b", "description": "", "templateType": "anything", "can_override": false}, "Theta_AB": {"name": "Theta_AB", "group": "Ungrouped variables", "definition": "degrees(Arctan((fric_a+fric_b)/(weight_crate_a+weight_crate_b)))", "description": "", "templateType": "anything", "can_override": false}}, "variablesTest": {"condition": "", "maxRuns": 100}, "ungrouped_variables": ["Acc_Grav", "mass_crate_A", "mass_crate_B", "co_eff_A", "Co_eff_B", "Theta_A", "Theta_B", "Weight_Crate_A", "Weight_Crate_B", "fric_A", "fric_b", "Theta_AB"], "variable_groups": [], "functions": {}, "preamble": {"js": "", "css": ""}, "parts": [{"type": "information", "useCustomName": false, "customName": "", "marks": 0, "scripts": {}, "customMarkingAlgorithm": "", "extendBaseMarkingAlgorithm": true, "unitTests": [], "showCorrectAnswer": true, "showFeedbackIcon": true, "variableReplacements": [], "variableReplacementStrategy": "originalfirst", "nextParts": [], "suggestGoingBack": false, "adaptiveMarkingPenalty": 0, "exploreObjective": null, "prompt": "

Part a) Calculate (to within 1 decimal place) the angle θ when Crate A begins to slide.

[7 Marks]

"}, {"type": "information", "useCustomName": false, "customName": "", "marks": 0, "scripts": {}, "customMarkingAlgorithm": "", "extendBaseMarkingAlgorithm": true, "unitTests": [], "showCorrectAnswer": true, "showFeedbackIcon": true, "variableReplacements": [], "variableReplacementStrategy": "originalfirst", "nextParts": [], "suggestGoingBack": false, "adaptiveMarkingPenalty": 0, "exploreObjective": null, "prompt": "

Part b) Calculate (to within 1 decimal place) the angle θ when Crate B begins to slide.

[2 Marks]

Part c) If the 2 masses are connected at points C & D by a cable.

Calculate the angle (to within 1 decimal place) the two joined crates begin to slide.

[6 Marks]

Ensure you include a free body diagram in your workings.

[5 Marks]

"}], "partsMode": "all", "maxMarks": 0, "objectives": [], "penalties": [], "objectiveVisibility": "always", "penaltyVisibility": "always", "contributors": [{"name": "Robert Bauld", "profile_url": "https://numbas.mathcentre.ac.uk/accounts/profile/19446/"}]}]}], "contributors": [{"name": "Robert Bauld", "profile_url": "https://numbas.mathcentre.ac.uk/accounts/profile/19446/"}]}