We have learned about Arithmetic sequences in detail in our Arithmetic progressions - calculator free lesson. It is important to practice these types of questions both with and without the use of a calculator.
We can use a CAS calculator to:
For any arithmetic sequence with starting value $a$a and common difference $d$d, we can express it in either of the following two forms:
$t_n=t_{n-1}+d$tn=tn−1+d, where $t_1=a$t1=a or alternatively $t_{n+1}=t_n+d$tn+1=tn+d, where $t_1=a$t1=a
This can be referred to as the recursive rule/equation for the arithmetic progression.
$t_n=a+\left(n-1\right)d$tn=a+(n−1)d
This can be referred to as the explicit rule, the general rule or the rule for the nth term.
Select the brand of calculator you use below to work through an example of using a calculator for arithmetic sequences and then try the practice questions.
Casio Classpad
How to use the CASIO Classpad to complete the following tasks regarding arithmetic sequences.
Generate the first $10$10 terms of the sequence with the recursive relationship: $t_n=t_{n-1}+4,t_1=3$tn=tn−1+4,t1=3
Generate the first $10$10 terms of the sequence with the explicit relationship: $t_n=7+3n$tn=7+3n
Find the $100$100th term of the sequence $t_n=t_{n-1}+2.5$tn=tn−1+2.5, $t_1=8$t1=8.
Given the third term of an arithmetic sequence is $20$20 and the $12$12th term is $56$56. Use your calculator to find the explicit rule for the sequence in the form $t_n=a+(n-1)d$tn=a+(n−1)d.
TI Nspire
How to use the TI Nspire to complete the following tasks regarding arithmetic sequences.
Generate the first $10$10 terms of the sequence with the recursive relationship: $t_n=t_{n-1}+4,t_1=3$tn=tn−1+4,t1=3
Generate the first $10$10 terms of the sequence with the explicit relationship: $t_n=7+3n$tn=7+3n
Find the $100$100th term of the sequence $t_n=t_{n-1}+2.5$tn=tn−1+2.5, $t_1=8$t1=8.
Given the third term of an arithmetic sequence is $20$20 and the $12$12th term is $56$56. Use your calculator to find the explicit rule for the sequence in the form $t_n=a+(n-1)d$tn=a+(n−1)d.
Study the pattern for the following sequence:
$-6,-\frac{62}{9},-\frac{70}{9},-\frac{26}{3},\ldots$−6,−629,−709,−263,…
State the common difference between consecutive terms.
Consider the following sequence.
Each term is obtained by increasing the previous term by $35$35. The first term is $60$60.
Write a recursive rule for $T_{n+1}$Tn+1 in terms of $T_n$Tn which defines the sequence below, and an initial condition for $T_1$T1.
Enter both parts on the same line separated by a comma.
Consider the sequence defined by $a_1=6$a1=6 and $a_n=a_{n-1}+5$an=an−1+5 for $n\ge2$n≥2.
What is the $21$21st term of the sequence?
What is the $22$22nd term of the sequence?
What is the $23$23rd term of the sequence?
What is the $24$24th term of the sequence?
What is the $25$25th term of the sequence?
Consider the first three terms of the following arithmetic sequence.
$9,15,21,\ldots$9,15,21,…
Determine $d$d, the common difference.
State the general rule for finding $T_n$Tn, the $n$nth term in the sequence.
Determine $T_9$T9, the $9$9th term in the sequence.
Find the $90$90th term in the sequence.
Solve for the value of $x$x such that $x+4$x+4, $4x+4$4x+4, and $10x-20$10x−20 form successive terms in an arithmetic progression.
In an arithmetic progression, $T_{11}=27$T11=27 and $T_{13}=31$T13=31.
By substituting $T_{11}=27$T11=27 into the equation $T_n=a+\left(n-1\right)d$Tn=a+(n−1)d, form an equation for $a$a in terms of $d$d.
By substituting $T_{13}=31$T13=31 into the equation $T_n=a+\left(n-1\right)d$Tn=a+(n−1)d, form another equation for $a$a in terms of $d$d.
Hence solve for the value of $d$d.
Hence solve for the value of $a$a.
Find $T_{10}$T10, the $10$10th term in the sequence.