1 / 26

Sec 2.1.5 How Arithmetic Sequences Work?

Sec 2.1.5 How Arithmetic Sequences Work?. Generalizing Arithmetic Sequences. Blast from the past. Solve the system of equations: x+9y=33 x+21y=-3. Test 2 Thursday Oct 31. Happy Halloween!. Yummm !. So far:. Linear function: Constant increase or decrease.

lenci
Download Presentation

Sec 2.1.5 How Arithmetic Sequences Work?

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Sec 2.1.5How Arithmetic Sequences Work? Generalizing Arithmetic Sequences

  2. Blast from the past • Solve the system of equations: x+9y=33 x+21y=-3

  3. Test 2Thursday Oct 31 Happy Halloween! Yummm!

  4. So far: • Linear function: • Constant increase or decrease. • Same value is added (or subtracted) to the output as the input increases by one unit. • Exponential function: • Constant growth or decay by a common ratio. • The output is multiplied (or divided) by a common ratio as the input increases by one unit.

  5. Next few lessons Arithmetic sequences: Constant increase or decrease. Geometric Sequences: Constant growth or decay by a common ratio.

  6. Arithmetic Sequences

  7. Some terms you should know before we start • Definition of Counting Numbers • The numbers which are used for counting from one to infinity are called Counting Numbers. • More about Counting Numbers • Counting numbers are also called as natural numbers. • Counting numbers are designated as n.

  8. Example on Counting Numbers Identify the counting numbes. A. 30B. 9.1C. 0D. 10 E. -2 F. 1

  9. A sequence can be thought of as a function, with the input numbers consisting of the natural numbers, and the output numbers being the terms.

  10. A sequence in which a constant (d) can be added to each term to get the next term is called an Arithmetic Sequence. Definition The constant (d) is called the Common Difference.

  11. To find the common difference (d), subtract any term from one that follows it. t1 t2 t3 t4 t5 2 5 8 11 14 Definition 3 3 3 3

  12. Find the first term and the common difference of each arithmetic sequence. Examples: First term (a): 4 Common difference (d): = 9 – 4 = 5 First term (a): 34 -7 Common difference (d): BE CAREFUL: ALWAYS CHECK TO MAKE SURE THE DIFFERENCE IS THE SAME BETWEEN EACH TERM !

  13. Now you try! Find the first term and the common difference of each of these arithmetic sequences. a) 1, -4, -9, -14, …. b) 11, 23, 35, 47, …. c) 3x-8, x-8, -x-8, -3x-8 d) s-4, 3s-3, 5s-2, 7s-1, …..

  14. Answers with solutions a) 1, -4, -9, -14, …. a = 1 and d = a2 - a1= - 4 - 1 = - 5 a = 11 and d = a2 - a1= 23 - 11 = 12 b) 11, 23, 35, 47, …. a = 3x-8 and d = a2 - a1= x – 8 – (3x – 8) = - 2x c) 3x-8, x-8, -x-8, -3x-8 a = s - 4 and d = a2 - a1= 3s – 3 – (s – 4) = 2s + 1 d) s-4, 3s-3, 5s-2, 7s-1, …..

  15. The first term of an arithmetic sequence is (a) . We add (d) to get the next term. There is a pattern, therefore there is a formula we can use to give use any term that we need without listing the whole sequence . 3, 7, 11, 15, …. We know a = 3 and d = 4 t1= a = 3 t2= a+d = 3+4 = 7 t3= a+d+d = a+2d = 3+2(4) = 11 t4 = a+d+d+d = a+3d = 3+3(4) = 15

  16. The first term of an arithmetic sequence is (a) . We add (d) to get the next term. There is a pattern, therefore there is a formula we can use to give use any term that we need without listing the whole sequence . The nth term of an arithmetic sequence is given by: tn = t1 + (n – 1) d The last # in the sequence/or the # you are looking for The position the term is in First term The common difference

  17. Explicit Formula of a Sequence • A formula that allows direct computation of any term for a sequence a1, a2, a3, . . . , an, . . . . • To determine the explicit formula, the pervious term need not be computed.

  18. You are looking for the term! Examples: Find the 14th term of the arithmetic sequence 4, 7, 10, 13,…… tn = t1 + (n – 1) d t14 = The 14th term in this sequence is the number 43!

  19. Now you try! Find the 10th and 25th term given the following information. Make sure to derive the general formula first and then list ehat you have been provided. a) 1, 7, 13, 19 …. b) x+10, x+7, x+4, x+1, …. c) The first term is 3 and the common difference is -21 d) The second term is 8 and the common difference is 3

  20. Answers with solutions a = 1 and d = a2 - a1= 7 – 1 = 6 tn=a+(n-1)d = 1 + (n-1) 6 = 1+6n-6 So tn = 6n-5 t10 = 6(10) – 5 = 55 t25 = 6(25)-5 = 145 a) 1, 7, 13, 19 …. …. a = x+10and d = a2 - a1= x+7-(x+10) = -3 tn=a+(n-1)d = x+10 + (n-1)(-3) = x+10-3n+3So tn= x-3n+13 t10 = x -3(10)+13 = x - 17 t25 = x -3(25)+13 = x - 62 b) x+10, x+7, x+4, x+1,. a = 3and d = -21 tn=a+(n-1)d = 3 + (n-1) -21 = 3-21n+21So tn= 24-21n t10 = 24-21(10) = -186 t25 = 24-21(25) = -501 c) The first term is 3 and the common difference is -21 d) The second term is 8 and the common difference is 3 a = 8 - 3 = 5and d = 3 tn=a+(n-1)d = 5 + (n-1) 3 = 5+3n-3 So tn = 3n+2 t10 = 3(10) +2 = 32 t25 = 3(25)+2 = 77

  21. You are looking for the term! List which variables from the general term are provided! Examples: Find the 14th term of the arithmetic sequence with first term of 5 and the common difference is –6. a = 5 and d = -6 tn = a + (n – 1) d t14 = -6 5 = 5 + (13) * -6 = 5 + -78 = -73 The 14th term in this sequence is the number -73!

  22. You are looking for n! Examples: In the arithmetic sequence 4,7,10,13,…, which term has a value of 301? tn = t1 + (n – 1) d The 100th term in this sequence is 301!

  23. You are looking for n! Examples: In the arithmetic sequence 4,7,10,13,…, Can a term be 560? tn = t1 + (n – 1) d 560 is not a term.

  24. t10=33 t22= -3 Use what you know! tn = t1 + (n – 1) d tn = t1 + (n – 1) d For term 22: -3= a + 21d For term 10: 33= a + 9d Examples: In an arithmetic sequence, term 10 is 33 and term 22 is –3. What are the first four terms of the sequence? HMMM! Two equations you can solve! SOLVE: 33 = a+9d -3 = a+21d By elimination -36 = 12d -3 = d SOLVE: 33 = a + 9d 33 = a +9(-3) 33 = a –27 60 = a The sequence is 60, 57, 54, 51, …….

  25. Recursive Formula • For a sequences a1, a2, a3, . . . , an, . . . a recursive formula is a formula that requires the computation of all previous terms in order to find the value of an .

  26. homework • Review and Preview • Page 78 • #71-77 all • For additional resources use this page: • http://mathbits.com/MathBits/TISection/Algebra2/sequences.htm

More Related