Understanding Limits in Calculus Through Visual Presentations
Explore the concepts of limits, continuity, asymptotes, area problems, and tangent line problems in calculus using visual aids and explanations. Learn how limits behave as variables approach specific values and understand the relationship between functions and their behaviors near critical points. Dive into the world of calculus with engaging visuals and clear explanations presented by Lin McMullin.
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Teaching Limits so that Students will Understand Limits Presented by Lin McMullin
Continuity + + 3 2 4 6 x x x ( ) f x = 2 x What happens at x = 2? What is f(2)? What happens near x = 2? f(x) is near 3 What happens as x approaches 2? f(x) approaches 3
Asymptotes 1 ( ) = g x ( ) 2 1 x What happens at x = 1? What happens near x = 1? As x approaches 1, g increases without bound, or g approaches infinity. As x increases without bound, g approaches 0. As x approaches infinity g approaches 0.
x x-1 1/(x-1)^2 Asymptotes 0.9 -0.1 100.00 0.91 -0.09 123.46 0.92 -0.08 156.25 1 0.93 -0.07 204.08 ( ) = g x 0.94 -0.06 277.78 ( ) 2 1 x 0.95 -0.05 400.00 0.96 -0.04 625.00 0.97 -0.03 1,111.11 0.98 -0.02 2,500.00 0.99 -0.01 10,000.00 1 0 Undefined 1.01 0.01 10,000.00 1.02 0.02 2,500.00 1.03 0.03 1,111.11 1.04 0.04 625.00 1.05 0.05 400.00 1.06 0.06 277.78 1.07 0.07 204.08 1.08 0.08 156.25 1.09 0.09 123.46 1.10 0.1 100.00
Asymptotes x x-1 1/(x-1)^2 1 ( ) = g x 1 0 Undefined ( ) 2 1 x 2 1 1 5 4 0.0625 10 9 0.01234567901234570 50 49 0.00041649312786339 100 99 0.00010203040506071 500 499 0.00000401604812832 1,000 999 0.00000100200300401 10,000 9999 0.00000001000200030 100,000 99999 0.00000000010000200 1,000,000 999999 0.00000000000100000 10,000,000 9999999 0.00000000000001000 100,000,000 99999999 0.00000000000000010
The Area Problem ( ) ( ) j x x x = = + = 2 1 h x x 0 = 1 3 What is the area of the outlined region? As the number of rectangles increases with out bound, the area of the rectangles approaches the area of the region.
The Tangent Line Problem What is the slope of the black line? As the red point approaches the black point, the red secant line approaches the black tangent line, and The slope of the secant line approaches the slope of the tangent line.
As x approaches 1, (5 2x) approaches ? 5 2x x 0.90 3.20 0.91 3.18 0.92 3.16 0.93 3.14 0.94 3.12 0.95 3.10 f(x) within 0.16 units of 3 x within 0.08 units of 1 f(x) within 0.08 units of 3 x within 0.04 units of 1 0.96 3.08 0.97 3.06 0.98 3.04 0.99 3.02 1.00 3.00 1.01 2.98 1.02 2.96 1.03 2.94 1.04 2.92 1.05 2.90 1.06 2.88 1.07 2.86 1.08 2.84 1.09 2.82
( ) lim 5 x 2 x 3 = 1 1 x 2 2 2 x 2 2 x 5 2 3 x ( ) 5 2 3 x ( ) f x L
( ) lim 5 x 2 x 3 = 1 ( ) 5 2 3 x or + 3 5 2 3 x Graph + 1 or 1 1 x x 2 2 2
( ) lim 5 x 2 x 3 = 1 = = = 4 2
The Definition of Limit at a Point When the values successively attributed to a variable approach indefinitely to a fixed value, in a manner so as to end by differing from it as little as one wishes, this last is called the limit of all the others. Augustin-Louis Cauchy (1789 1857)
The Definition of Limit at a Point ( ) x = lim x if, and only if, for any number 0 f L a ( ) there is a number 0 such t hat ( ) ( ) f x if 0 , then x a L Karl Weierstrass (1815 1897)
The Definition of Limit at a Point ( ) x = lim x if, and only if, for any number 0 f L a ( ) there is a number 0 such t hat ( ) ( ) f x if 0 , then x a L ( ) f x = lim x if, and only if, for any number 0 L a ( ) + there is a numb er 0 and such t hat x a ( ) ( ) ( ) f x + i f , then a x a L L Karl Weierstrass (1815 1897)
Footnote: The Definition of Limit at a Point ( ) = lim x 0 0 such that af x L ( ) f x , whenever 0 x a L
Footnote: The Definition of Limit at a Point ( ) = lim x 0 0 such that af x L ( ) f x x a , whe never 0 L
The Definition of Limit at a Point ( ) x = lim x if, and only if, for any number 0 f L a ( ) there is a number 0 such t hat ( ) ( ) f x if 0 , then x a L
( ) lim 5 x 2 x 3 = 1 5 2x x 0.90 3.20 0.91 3.18 0.92 3.16 0.93 3.14 0.94 3.12 0.95 3.10 f(x) within 0.16 units of 3 x within 0.08 units of 1 f(x) within 0.08 units of 3 x within 0.04 units of 1 0.96 3.08 0.97 3.06 0.98 3.04 0.99 3.02 1.00 3.00 1.01 2.98 1.02 2.96 1.03 2.94 1.04 2.92 1.05 2.90 1.06 2.88 1.07 2.86 1.08 2.84 1.09 2.82
( ) lim 5 x 2 x 3 = 1 ( ) f x L ( ) 5 2 3 x 5 2 3 x 2 2 x 2 2 x 1 x 2
lim x x 9 2 = 3 2 9 x + 3 3 x x
lim x x 9 2 = 3 2 9 x + 3 3 x x = + Near 3, specifically in (2,4), 5 3 7 x x
lim x x 9 2 = 3 2 9 x + 3 3 x x = + Near 3, specifically in (2,4), 5 3 7 x x 7 3 x 3 x 7
lim x x 9 2 = 3 2 9 x + 3 3 x x = + Near 3, specifically in (2,4), 5 3 7 x x 7 3 x 3 x 7 ( ) = the smaller of 1 and 7 Graph
Length of Blue Arc = | x - a | lim sin( ) x a x sin( ) a = Length of Red Segment = | sin(x) - sin(a) | Therefore, | sin(x) - sin(a) | < | x - a | = Let (0,1) ( ) x ( ) a (cos x, sin x) a + delta x a sin sin ( ) x ( ) a sin sin ( ) x = ( ) a x a sin sin (cos a, sin a) ( ) ( ) x ( ) a lim sin x a sin sin x a - delta x in radians sin a (1, 0) Graph
One-sided Limits ( ) f x = lim x if, and only if, for any number 0 L + a ( ) there is a number 0 such that ( ) ( ) f x if 0 , then x a L ( ) f x = lim x if, and only if, for any number 0 L a ( ) there is a number 0 such that ( ) hen f x ( ) if 0 , t a x L
Limits Equal to Infinity ( ) f x = lim x if, and only if, for any number 0 M a ( ) there is a number such that ( ) ( ) ( ) f x ( ) f x if 0 , then x a M M Graphically this is a vertical asymptote ( ) = lim x if, and only if, for any number 0 af x M ( ) , then there is a number such that ( ) ( ) f x if 0 x a M
Limit as x Approaches Infinity ( ) f x = lim x if, and only if, for any number 0 L there is a number 0 suc h that M ( ) f x if , then x M L Graphically, this is a horizontal a sym t p ote ( ) f x = lim x if, and only if, for any number 0 L there is a number 0 such that M ( ) f x if , then x M L
Limit Theorems Almost all limit are actually found by substituting the values into the expression, simplifying, and coming up with a number, the limit. The theorems on limits of sums, products, powers, etc. justify the substituting. Those that don t simplify can often be found with more advanced theorems such as L'H pital's Rule
The Area Problem ( ) ( ) j x x x = = + = 2 1 h x x 0 = 1 3
The Area Problem ( ) h x b a n ( ) j x = = + 2 length 1 2 n x 3 1 n = = = width ( ) 2 ,1 ( ) 3 ,...,1 ( ) n + + + + x-coordinates = 1,1 ,1 2 n 2 n 2 n 2 n ( )( ) n ( ) 2 + + Area 1 1 i 2 n 2 n = 1 i ( )( ) 32 3 n ( ) 2 + + = Area =lim 1 1 i 2 n 2 n n = 1 i
The Area Problem ( )( ) n n n n ( ) 2 + + = 2 lim + + 2 lim i 1 1 lim n lim n i i i 2 n 2 n 2 n 2 n 4 n 2 n 4 n 2 n = = = = 1 1 1 1 i i i i n n n = + + 2 lim n 1 lim n lim n i i 8 n 8 n 4 n 2 3 = = = 1 + 1 1 i i i ( ) ( )( 6 ) + 1 2 + + 1 1 n n n n n = + lim n lim n lim n n 8 n 8 n 4 n 2 2 3 4 4 = + + = 8 3 32 3
The Tangent Line Problem As x P T ( ) ( ) 0 + + , P a x f a x slope f a PT + + m ( ) x ( ) f a a x m ( ) ( ) f a ( ) + f a x a ( ) ( ) , T a f a x ( ) f a ( ) = + x a y m
The Tangent Line Problem As x P T 0 ( ) ( ) + + , P a x f a x slope f PT + m ( ) x ( ) f a a a x ( ) a f ( ) ( ) ( ) f a + a + f a x ( ) ( ) , T a f a x ( ) f a ( )( a ) f = + x a y
Lin McMullin lnmcmullin@aol.com teachingcalculus.wordpress.com www.LinMcMullin.net Click: AP Calculus
Teaching Limits so that Students will Understand Limits Presented by Lin McMullin
