// Numbas version: finer_feedback_settings {"name": "Differentiation 13 - Quotient Rule", "extensions": [], "custom_part_types": [], "resources": [], "navigation": {"allowregen": true, "showfrontpage": false, "preventleave": false, "typeendtoleave": false}, "question_groups": [{"pickingStrategy": "all-ordered", "questions": [{"extensions": [], "preamble": {"css": "fraction {\n display: inline-block;\n vertical-align: middle;\n}\nfraction > numerator, fraction > denominator {\n float: left;\n width: 100%;\n text-align: center;\n line-height: 2.5em;\n}\nfraction > numerator {\n border-bottom: 1px solid;\n padding-bottom: 5px;\n}\nfraction > denominator {\n padding-top: 5px;\n}\nfraction input {\n line-height: 1em;\n}\n\nfraction .part {\n margin: 0;\n}\n\n.table-responsive, .fractiontable {\n display:inline-block;\n}\n.fractiontable {\n padding: 0; \n border: 0;\n}\n\n.fractiontable .tddenom \n{\n text-align: center;\n}\n\n.fractiontable .tdnum \n{\n border-bottom: 1px solid black; \n text-align: center;\n}\n\n\n.fractiontable tr {\n height: 3em;\n}\n", "js": "document.createElement('fraction');\ndocument.createElement('numerator');\ndocument.createElement('denominator');"}, "variable_groups": [], "variablesTest": {"condition": "", "maxRuns": 100}, "metadata": {"licence": "Creative Commons Attribution 4.0 International", "description": "

An introduction to using the quotient rule

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Differentiate the following expressions with respect to $x$ using the quotient rule.

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Simplify your answers as much as possible.

", "variables": {"c": {"templateType": "anything", "group": "Ungrouped variables", "name": "c", "definition": "repeat(random(-9..9 except 0),12)", "description": ""}, "p": {"templateType": "anything", "group": "Ungrouped variables", "name": "p", "definition": "repeat(random(2..7),6)", "description": ""}}, "parts": [{"expectedvariablenames": ["x"], "checkvariablenames": true, "checkingtype": "absdiff", "showFeedbackIcon": false, "type": "jme", "vsetrange": [0, 1], "scripts": {}, "marks": "3", "prompt": "

$x$$\\simplify{x+{c[0]}}$

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$\\simplify{x^{p[0]}}$$\\simplify{{c[4]}x+{c[5]}}$

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These questions use the quotient rule.

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The quotient rule is defined as

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$\\frac{dy}{dx}=\\frac{v\\frac{du}{dx}+u\\frac{dv}{dx}}{v^2}$

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when $y=\\frac{u}{v}$

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Worked example using Part a:

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$x$$\\simplify{x+{c[0]}}$

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This expression is the result of $x$ divided by ($\\simplify{x+{c[0]}}$).

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We can therefore say:

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$u=x$

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and

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$v=\\simplify{x+{c[0]}}$,

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Hence meaning that $y=\\frac{u}{v}$.

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We already have what $u$ and $v$ equal, so all we have to do is find what $\\frac{du}{dx}$ and $\\frac{dv}{dx}$ are, and then substitute everything into the rule.

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Differentiating with respect to $x$, we get:

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$\\frac{du}{dx}=1$

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and

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$\\frac{dv}{dx}=1$.

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As there are no powers or coefficients of $x$ that are $>1$, this is a very simple version of the quotient rule, but knowing how to work out this equation formally will make more difficult looking problems just as simple.

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Substituting in all the results we've found, we get:

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$\\frac{dy}{dx}=\\frac{1(\\simplify{x+{c[0]}})+1(x)}{\\simplify{(x+{c[0]})^2}}$

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We then simplify, collecting all the terms, to get our final answer of:

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$\\frac{dy}{dx}=\\simplify{((2x+{c[0]}))/(x+{c[0]})^2}$

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