class: center, middle, inverse, title-slide # 1.3 — Preferences ## ECON 306 • Microeconomic Analysis • Spring 2021 ### Ryan Safner
Assistant Professor of Economics
safner@hood.edu
ryansafner/microS21
microS21.classes.ryansafner.com
--- class: inverse # Outline ### [Preferences](#3) ### [Indifference Curves](#10) ### [Marginal Rate of Substitution](#26) ### [Utility](#32) ### [Marginal Utility](#43) --- class: inverse, center, middle # Preferences --- # Preferences I .pull-left[ - Which bundles are **preferred** over others? .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**:] Between two bundles of `\((x,y)\)`: `$$a=(4,12) \text{ or } b=(6,12)$$` ] ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Preferences II .pull-left[ - We will allow **three possible answers**: ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Preferences II .pull-left[ - We will allow **three possible answers**: .content-box-blue[ 1. .blue[`\\(a \succ b\\)`: (Strictly) prefer `\\(a\\)` over `\\(b\\)`] ] ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Preferences II .pull-left[ - We will allow **three possible answers**: .content-box-blue[ 1. .blue[`\\(a \succ b\\)`: (Strictly) prefer `\\(a\\)` over `\\(b\\)`] 2. .blue[`\\(a \prec b\\)`: (Strictly) prefer `\\(b\\)` over `\\(a\\)`] ] ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Preferences II .pull-left[ - We will allow **three possible answers**: .content-box-blue[ 1. .blue[`\\(a \succ b\\)`: (Strictly) prefer `\\(a\\)` over `\\(b\\)`] 2. .blue[`\\(a \prec b\\)`: (Strictly) prefer `\\(b\\)` over `\\(a\\)`] 3. .blue[`\\(a \sim b\\)`: Indifferent between `\\(a\\)` and `\\(b\\)`] ] ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Preferences II .pull-left[ - We will allow **three possible answers**: .content-box-blue[ 1. .blue[`\\(a \succ b\\)`: (Strictly) prefer `\\(a\\)` over `\\(b\\)`] 2. .blue[`\\(a \prec b\\)`: (Strictly) prefer `\\(b\\)` over `\\(a\\)`] 3. .blue[`\\(a \sim b\\)`: Indifferent between `\\(a\\)` and `\\(b\\)`] ] - .hi[*Preferences*] **are a list of all such comparisons between all bundles** See appendix in [today's class page](/content/1.3-content/#appendix-1-material-on-preferences) for more. ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- class: inverse, center, middle # Indifference Curves --- # Mapping Preferences Graphically I .pull-left[ - For each bundle, we now have 3 pieces of information: - amount of `\(x\)` - amount of `\(y\)` - preference compared to other bundles - How to represent this information graphically? ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Mapping Preferences Graphically II .pull-left[ - Cartographers have the answer for us - On a map, **contour lines** link areas of **equal height** - We will use .hi["indifference curves"] to link bundles of **equal preference** ] .pull-right[ .center[ ![](../images/contourmap.jpg) ] ] --- # Mapping Preferences Graphically III .pull-left[ .center[ 3-D "Mount Utility"
] ] .pull-right[ .center[ 2-D Indifference Curve Contours <img src="1.3-slides_files/figure-html/unnamed-chunk-2-1.png" width="504" style="display: block; margin: auto;" /> ] ] --- # Indifference Curves: Example .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: Suppose you are hunting for an apartment. You value *both* the size of the apartment and the number of friends that live nearby. ] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-0-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: Suppose you are hunting for an apartment. You value *both* the size of the apartment and the number of friends that live nearby. - Apt. *A* has 1 friend nearby and is 1,200 `\(ft^2\)` ] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-1-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: Suppose you are hunting for an apartment. You value *both* the size of the apartment and the number of friends that live nearby. - Apt. *A* has 1 friend nearby and is 1,200 `\(ft^2\)` - Apartments that are larger and/or have more friends `\(\succ A\)` ] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-2-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: Suppose you are hunting for an apartment. You value *both* the size of the apartment and the number of friends that live nearby. - Apt. *A* has 1 friend nearby and is 1,200 `\(ft^2\)` - Apartments that are larger and/or have more friends `\(\succ A\)` - Apartments that are smaller and/or have fewer friends `\(\prec A\)` ] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-3-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: - Apt. *A* has 1 friend nearby and is 1,200 `\(ft^2\)` - Apt. *B* has *more* friends but *less* `\(ft^2\)` ] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-4-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: - Apt. *A* has 1 friend nearby and is 1,200 `\(ft^2\)` - Apt. *B* has *more* friends but *less* `\(ft^2\)` - Apt. *C* has *still more* friends but *less* `\(ft^2\)` ] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-5-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: - Apt. *A* has 1 friend nearby and is 1,200 `\(ft^2\)` - Apt. *B* has *more* friends but *less* `\(ft^2\)` - Apt. *C* has *still more* friends but *less* `\(ft^2\)` - `\(A \sim B \sim C\)`: on same .hi[indifference curve] ] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-6-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ - .hi-blue[Indifferent] between all apartments on the **same** curve ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-8-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ - .hi-blue[Indifferent] between all apartments on the **same** curve - Apts **above** curve are .hi-green[preferred over] apts on curve - `\(D \succ A \sim B \sim C\)` - On a .hi-green[higher curve] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-10-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Indifference Curves: Example .pull-left[ - .hi-blue[Indifferent] between all apartments on the **same** curve - Apts **above** curve are .hi-green[preferred over] apts on curve - `\(D \succ A \sim B \sim C\)` - On a .hi-green[higher curve] - Apts **below** curve are .hi-red[less preferred] than apts on curve - `\(E \prec A \sim B \sim C\)` - On a .hi-red[lower curve] ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-ex-11-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Curves Never Cross! .pull-left[ - .hi-purple[Indifference curves can never cross]: preferences are .hi[transitive] - If I prefer `\(A \succ B\)`, and `\(B \succ C\)`, I must prefer `\(A \succ C\)` ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-as-4-1.png" width="432" style="display: block; margin: auto;" /> ] --- # Curves Never Cross! .pull-left[ - .hi-purple[Indifference curves can never cross]: preferences are .hi[transitive] - If I prefer `\(A \succ B\)`, and `\(B \succ C\)`, I must prefer `\(A \succ C\)` - Suppose two curves crossed: - .blue[`\\(A \sim B\\)`] - .orange[`\\(B \sim C\\)`] - But .orange[`\\(C\\)`] `\(\succ\)` .blue[`\\(B\\)`]! - Doesn't make sense (not transitive)! ] .pull-right[ <img src="1.3-slides_files/figure-html/IC-as-41-1.png" width="432" style="display: block; margin: auto;" /> ] --- class: inverse, center, middle # Marginal Rate of Substitution --- # Marginal Rate of Substitution I .pull-left[ - If I take away one friend nearby, how many more `\(ft^2\)` would you need to keep you satisfied? ] .pull-right[ .center[ ![:scale 80%](../images/scale.png) ] ] --- # Marginal Rate of Substitution I .pull-left[ - If I take away one friend nearby, how many more `\(ft^2\)` would you need to keep you satisfied? - .hi[Marginal Rate of Substitution (MRS)]: rate at which you trade off one good for more of the other and remain *indifferent* - Think of this as the .hi-purple[relative value] you place on x: > “I am willing to give up `\((MRS)\)` units of `\(y\)` to consume 1 more unit of `\(x\)` and stay satisfied.” ] .pull-right[ .center[ ![:scale 80%](../images/scale.png) ] ] --- # Marginal Rate of Substitution II .center[ ![](../images/mrsmeme.jpg) ] --- # Marginal Rate of Substitution II .pull-left[ - MRS `\(=\)` .hi[slope of the indifference curve] `$$MRS_{x,y}=-\frac{\Delta y}{\Delta x} = \frac{rise}{run}$$` - Amount of `\(y\)` given up for 1 more `\(x\)` - Note: slope (MRS) changes along the curve! ] .pull-right[ <img src="1.3-slides_files/figure-html/MRS-1.png" width="432" style="display: block; margin: auto;" /> ] --- # MRS vs. Budget Constraint Slope .pull-left[ - Budget constraint (slope) measured the **market's** tradeoff between `\(x\)` and `\(y\)` based on market prices - **MRS** measures your **personal** evaluation of `\(x\)` vs. `\(y\)` based on your preferences - **Foreshadowing**: what if they are *different*? Are you truly optimizing? ] .pull-right[ .center[ ![:scale 80%](../images/scale.png) ] ] --- class: inverse, center, middle # Utility --- # So Where are the Numbers? .pull-left[ - Long ago (1890s), utility considered a real, measurable, cardinal scale<sup>.hi[†]</sup> - Utility thought to be lurking in people's brains - Could be understood from first principles: calories, water, warmth, etc - Obvious problems ] .pull-right[ .center[ ![:scale 100%](../images/madlaboratory.jpg) ] ] .footnote[<sup>.hi[†]</sup> "Neuroeconomics" & cognitive scientists are re-attempting a scientific approach to measure utility] --- # Utility Functions? .pull-left[ - More plausibly .hi-turquoise[infer people's preferences from their actions]! - “Actions speak louder than words” - .hi-purple[Principle of Revealed Preference]: if a person chooses `\(x\)` over `\(y\)`, and both are affordable, then they must prefer `\(x \succeq y\)` - Flawless? Of course not. But extremely useful approximation! - People tend not to leave money on the table ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Utility Functions! .pull-left[ - A .hi[utility function] `\(u(\cdot)\)`<sup>.hi[†]</sup> *represents* preference relations `\((\succ , \prec , \sim)\)` - Assign utility numbers to bundles, such that, for any bundles `\(a\)` and `\(b\)`: `$$a \succ b \iff u(a)>u(b)$$` ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] .footnote[<sup>.hi[†]</sup> The `\\(\cdot\\)` is a placeholder for whatever goods we are considering (e.g. `\\(x\\)`, `\\(y\\)`, burritos, lattes, etc)] --- # Utility Functions, Pural I .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .hi-green[Example]: Imagine three alternative bundles of `\((x, y)\)`: `$$\begin{aligned} a&=(1,2)\\ b&=(2,2)\\ c&=(4,3)\\ \end{aligned}$$` ] ] -- .pull-right[ - Let `\(u(\cdot)\)` assign each bundle a utility level: | `\(u(\cdot)\)` | |------------| | `\(u(a)=1\)` | | `\(u(b)=2\)` | | `\(u(c)=3\)` | ] -- - .hi-turquoise[Does this mean that bundle `\\(c\\)` is 3 times the utility of `\\(a\\)`?] --- # Utility Functions, Pural II .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .hi-green[Example]: Imagine three alternative bundles of `\((x, y)\)`: `$$\begin{aligned} a&=(1,2)\\ b&=(2,2)\\ c&=(4,3)\\ \end{aligned}$$` ] ] .pull-left[ - Now consider `\(u(\cdot)\)` and a *2*<sup>*nd*</sup> function `\(v(\cdot)\)`: | `\(u(\cdot)\)` | `\(v(\cdot)\)` | |------------|------------| | `\(u(a)=1\)` | `\(v(a)=3\)` | | `\(u(b)=2\)` | `\(v(b)=5\)` | | `\(u(c)=3\)` | `\(v(c)=7\)` | ] --- # Utility Functions, Pural III .pull-left[ - Utility numbers have an .hi-purple[ordinal] meaning only, **not cardinal** - Both are valid utility functions:<sup>.hi[†]</sup> - `\(u(c)>u(b)>u(a)\)` ✅ - `\(v(c)>v(b)>v(a)\)` ✅ - because `\(c \succ b \succ a\)` - .hi-purple[Only the .ul[ranking] of utility numbers matters!] ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] .footnote[<sup>.hi[†]</sup> See the Mathematical Appendix in [Today's Class Page](content/1.3-content/#utility-functions-and-pmts) for why.] --- # Utility Functions and Indifference Curves I .pull-left[ - Two tools to represent preferences: .hi[indifference curves] and .hi[utility functions] - Indifference curve: all **equally preferred** bundles `\(\iff\)` **same utility level** - Each indifference curve represents one level (or contour) of utility surface (function) ] .pull-right[ .center[ ![](../images/choices.jpg) ] ] --- # Utility Functions and Indifference Curves II .pull-left[ .center[ 3-D Utility Function: `\(u(x,y)=\sqrt{xy}\)`
] ] .pull-right[ .center[ 2-D Indifference Curve Contours: `\(y=\frac{u^2}{x}\)` <img src="1.3-slides_files/figure-html/unnamed-chunk-4-1.png" width="504" style="display: block; margin: auto;" /> ] ] --- class: inverse, center, middle # Marginal Utility --- # MRS and Marginal Utility I .pull-left[ - Recall: .hi[marginal rate of substitution `\\(MRS_{x,y}\\)`] is slope of the indifference curve - Amount of `\(y\)` given up for 1 more `\(x\)` - How to calculate MRS? - Recall it changes (not a straight line)! - We can calculate it using something from the **utility function** ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-5-1.png" width="504" style="display: block; margin: auto;" /> ] --- # MRS and Marginal Utility II .pull-left[ - .hi[Marginal utility]: change in utility from a marginal increase in consumption ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-6-1.png" width="504" style="display: block; margin: auto;" /> ] --- # MRS and Marginal Utility II .pull-left[ - .hi[Marginal utility]: change in utility from a marginal increase in consumption .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Marginal utility of `\\(x\\)`**]: `\(MU_x = \frac{\Delta u(x,y)}{\Delta x}\)` ] ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-7-1.png" width="504" style="display: block; margin: auto;" /> ] --- # MRS and Marginal Utility II .pull-left[ - .hi[Marginal utility]: change in utility from a marginal increase in consumption .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Marginal utility of `\\(x\\)`**]: `\(MU_x = \frac{\Delta u(x,y)}{\Delta x}\)` ] .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Marginal utility of `\\(y\\)`**]: `\(MU_y = \frac{\Delta u(x,y)}{\Delta y}\)` ] ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-8-1.png" width="504" style="display: block; margin: auto;" /> ] --- # MRS and Marginal Utility II .pull-left[ - .hi[Marginal utility]: change in utility from a marginal increase in consumption .bg-washed-red.b--dark-red.ba.bw2.br3.shadow-5.ph4.mt5[ - .hi-red[Math (calculus)]: "*marginal*" means "*derivative with respect to*" `$$MU_x = \frac{\partial u(x,y)}{\partial x}$$` ] - I will always derive marginal utility functions for you ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-9-1.png" width="504" style="display: block; margin: auto;" /> ] --- # MRS and Marginal Utility: Example .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**:] For an example utility function `$$u(x,y) = x^2+y^3$$` - Marginal utility of x: `\(\quad MU_x = 2x\)` - Marginal utility of y: `\(\quad MU_y = 3y^2\)` ] - Again, I will always derive marginal utility functions for you --- # MRS Equation and Marginal Utility .pull-left[ - Relationship between `\(MU\)` and `\(MRS\)`: `$$\underbrace{\frac{\Delta y}{\Delta x}}_{MRS} = -\frac{MU_{x}}{MU_{y}}$$` - See proof in [today's class notes](/content/1.3-content/#derivation-of-mrs-equation-as-ratio-of-marginal-utilities) > “I am willing to give up `\(\left(\frac{MU_x}{MU_y}\right)\)` units of `\(y\)` to consume 1 more unit of `\(x\)` and stay satisfied.” ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-10-1.png" width="504" style="display: block; margin: auto;" /> ] --- # Important Insights About Value .pull-left[ > “I am willing to give up `\(\left(\frac{MU_x}{MU_y}\right)\)` units of `\(y\)` to consume 1 more unit of `\(x\)` and stay satisfied.” - We can't measure `\(MU\)`'s, but we *can* measure `\(MRS_{x,y}\)` and infer the **ratio** of `\(MU\)`'s! - .hi-green[Example]: if `\(MRS_{x,y} = 5\)`, a unit of good `\(x\)` gives 5 times the marginal utility of good `\(y\)` at the margin ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-11-1.png" width="504" style="display: block; margin: auto;" /> ] --- # Important Insights About Value .pull-left[ - Value is .hi-purple[subjective] - Each of us has our own preferences that determine our ends or objectives - Choice is .hi-turquoise[forward looking]: a comparison of your .hi-turquoise[expectations] about opportunities - .hi[Preferences are not comparable across individuals] - Only individuals know what they give up at the moment of choice ] .pull-right[ .center[ ![](../images/value2.png) ] ] --- # Important Insights About Value .pull-left[ - Value inherently comes from the fact that we must make .hi-purple[tradeoffs] - Making one choice means *having to give up* pursuing others! - The choice we pursue at the moment must be worth the sacrifice of others! (i.e. highest marginal utility) ] .pull-right[ .center[ ![](../images/value2.png) ] ] --- # Diminishing Marginal Utility .pull-left[ .hi-purple[The Law of Diminishing Marginal Utility]: each marginal unit of a good consumed tends to provide less marginal utility than the previous unit, all else equal - As you consume more `\(x\)`: - `\(\downarrow MU_x\)` - `\(\downarrow MRS_{x,y}\)`: willing to give up *fewer* units of `\(y\)` for `\(x\)` ] .pull-right[ .center[ ![:scale 50%](../images/icecreams.jpg) ] ] --- # Special Case: Substitutes .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: Consider 1-Liter bottles of coke and 2-Liter bottles of coke ] - Always willing to substitute between Two 1-L bottles for One 2-L bottle - .hi[Perfect substitutes]: goods that can be substituted at same fixed rate and yield same utility - `\\(MRS_{1L,2L}=-0.5\\)` (a constant!) ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-12-1.png" width="504" style="display: block; margin: auto;" /> ] --- # Special Case: Complements .pull-left[ .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .green[**Example**]: Consider hot dogs and hot dog buns ] - Always consume together in fixed proportions (in this case, 1 for 1) - .hi[Perfect complements]: goods that can be consumed together in same fixed proportion and yield same utility - `\\(MRS_{H,B}=\\)` ? ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-13-1.png" width="504" style="display: block; margin: auto;" /> ] --- # Cobb-Douglas Utility Functions .pull-left[ - A very common functional form in economics is .hi[Cobb-Douglas] `$$u(x,y)=x^ay^b$$` - Extremely useful, you will see it often! - Lots of nice, useful properties (we'll see later) - See the appendix in [today's class page](content/1.3-content/#cobb-douglas-functions) ] .pull-right[ <img src="1.3-slides_files/figure-html/unnamed-chunk-14-1.png" width="504" style="display: block; margin: auto;" /> ] --- # Practice .bg-washed-green.b--dark-green.ba.bw2.br3.shadow-5.ph4.mt5[ .smallest[ .green[**Example**]: Suppose you can consume apples `\((a)\)` and broccoli `\((b)\)`, and earn utility according to: `$$\begin{align*} u(a,b)&=2ab\\ MU_a&=2b\\ MU_b&=2a\\ \end{align*}$$` 1. Put `\(a\)` on the horizontal axis and `\(b\)` on the vertical axis. Write an equation for `\(MRS_{a,b}\)`. 2. Would you prefer a bundle of `\((1, 4)\)` or `\((2, 2)\)`? 3. Suppose you are currently consuming 1 apple and 4 broccoli. a. How many units of broccoli are you willing to give up to eat 1 more apple and remain indifferent? b. How much *more* utility would you get if you were to eat 1 more apple? 4. Repeat question 3, but for when you are consuming 2 of each good. ] ]