Solving Simple Arcsine and Arccosine Equations

 Solving Simple Arcsine and Arccosine Equations

Angle Measure

This document will focus on angle measurement in degrees. For radians and grads, please use the appropriate measurement.

90° = π/2 rad = 100 grad

180° = π rad = 200 grad

Simple Arcsine Equations

The calculator arcsine function gives: Domain: -1 ≤ x ≤ 1, Range: -90° ≤ Θ ≤ 90°

Note that for any angle x: sin(180° - x) = sin(x), sin(x) = sin(x ± 360°*z) (z is an integer)

Given n, solve for Θ:

n = sin(Θ) = sin(180° - Θ)

Base Solution 1:

n = sin(Θ)

⇒ Θ = arcsin(n)

Base Solution 2:

n = sin(180° - Θ)

arcsin(n) = 180° - Θ

⇒ Θ = 180° - arcsin(n)

Example:

0.67 = sin(Θ)

Base Solution 1: Θ = arcsin(0.67) ≈ 42.0670648025°

Base Solution 2: Θ = 180° - arcsin(0.67) ≈ 137.932935198°

Given n and α, solve for Θ:

n = sin(α + Θ)

Base Solution 1:

n = sin(α + Θ)

arcsin(n) = α + Θ

⇒ Θ = arcsin(n) – α

Base Solution 2:

n = sin(180° - (α + Θ))

n = sin(180° - α – Θ)

arcsin(n) = 180° - α – Θ

⇒ Θ = 180° - α – arcsin(n)

Example:

0.7757 = sin(Θ + 76°)

Base Solution 1: Θ = arcsin(0.7757) – 76° ≈ -25.1314549842°

Base Solution 2: Θ = 180° - 76° - arcsin(0.7757) = 104° - arcsin(0.7757) ≈ 53.131459842°

To get all the possible angles, add and subtract multiples of 360°.

Solving Simple Arccosine Equations

The calculator arccosine function gives: Domain: -1 ≤ x ≤ 1, Range: -90° ≤ Θ ≤ 90°

Note that for any angle x: cos(180° - x) = -cos(x), cos(x) = cos(x ± 360°*z) (z is an integer)

Given n, solve for Θ:

n = cos(Θ), n = cos(-Θ)

Base Solution 1:

n = cos(Θ)

⇒ Θ = arccos(n)

Base Solution 2:

n = cos(-Θ)

⇒ Θ = -arccos(n)

Example:

0.58 = cos(Θ)

Base Solution 1: Θ = arccos(0.58) ≈ 54.54945736°

Base Solution 2: Θ = -arccos(0.58) ≈ -54.54945736°

Given n and α, solve for Θ:

n = cos(α + Θ)

Base Solution 1:

n = cos(α + Θ)

arccos(n) = α + Θ

⇒ Θ = arccos(n) – α

Base Solution 2:

n = cos(-(α + Θ))

n = cos(-α – Θ)

arccos(n) = -α – Θ

-arccos(n) = α + Θ

⇒ Θ = -arccos(n) – α

Example:

0.6 = cos(35° + Θ)

Base Solution 1: Θ = arccos(0.6) – 35° ≈ 18.13012035°

Base Solution 2: Θ = -arccos(0.6) – 35° ≈ -88.13010235°

To get all the possible angles, add and subtract multiples of 360°.

I hope you find this useful and helpful,

Eddie

All original content copyright, © 2011-2026. Edward Shore. Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited. This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.

HP 65 Programs: Triangulation, Percentile, Roots of Unity, Partial Fractions

 HP 65 Programs: Triangulation, Percentile, Roots of Unity, Partial Fractions

Triangulation

(done with HP-65 Emulator for Windows, Bernhard Emese)

Given:

Side angle α

Side angle ß

r = Length of base

Find:

h = height which crosses the base line at right angles

Code:

23: LBL

12: B

35: g

41: DEG

33 01: STO 1

35 08: R↓

41: ENTER

41: ENTER

44: CLX

51: -

31: f

04: SIN

35 09: R↑

31: f

04: SIN

71: *

33: STO

71: *

01: 1

35 08: R↓

61: +

31: f

04: SIN

33: STO

81: ÷

01: 1

34 01: RCL 1

24: RTN

Example: ß = 50°, α = 30°, r = 10

Result: h ≈ 3.89

Source:

“Triangulation (surveying)” Wikipedia. https://en.wikipedia.org/wiki/Triangulation (surveying) (last edited October 24, 2025). Retried March 17, 2026

Percentile in a Range

The program calculates the percentile of x in the range [a, b].

percentile = (x – a) ÷ (b – a) * 100%

Stack:

Z: x

Y: a

X: b

23: LBL

11: B

35 07: x<>y

51: -

35 00: LSTx

35 07: R↓

51: -

35 09: R↑

81: ÷

02: 2

32: f^-1

08: LOG (10^x)

71: ×

24: RTN

Example: The range: [210, 470], x = 376

Stack: Z: 376, Y: 210, X: 470

Result: 63.85

Roots of Unity

(done with HP-65 Emulator for Windows, Bernhard Emese)

w^n = 1

Registers used: R1 = n, R8 = n (counter)

n [ A ]

Cycle:

root # [ R/S ]

real part [ R/S ]

imaginary part [ R/S ] (the cycle starts again)

Repeat the cycle until the display is flashing zeros (forced 1/0 error). Hit [ CLx ] to stop the flashing.

This program switches the mode to radians angle measurement.

Code:

23: LBL

11: A

33 01: STO 1

33 08: STO 8

35: g

42: RAD

23: LBL

00: 0 (LBL 0 - subroutine)

34 08: RCL 8

84: R/S (show root #)

35: g

02: π

71: ×

02: 2

71: ×

34 01: RCL 1

81: ÷

01: 1

32: f^-1

01: R->P (->rect)

84: R/S (show real part)

35 07: x<>y

84: R/S (show imaginary part)

35: g

83: DSZ (decrement R8 by 1)

22: GTO

00: 0 (GOTO LBL 0)

34 08: RCL 8

35: g

04: 1/x

24: RTN

Example (FIX 4):

w^3 = 1

#; R/S; real part; R/S; imaginary part

3; 1.0000; -0.0000

2; -0.5000; -0.8660

1; -0.5000; 0.8660

(flashing zeroes)

Partial Fractions

(w is the variable, and T, Z, Y, and X are the stack contents)

(Tw+Z) ÷ ((w+Y)(w+X)) → B÷(w+Y) + A÷(w+X)

Input Stack: T, Z, Y, X 

Output Stack: B, A

Code: 

23: LBL 

11: A 

35, 07: x<>y 

51: - 

35, 00: LST x 

35, 09: R↑ 

71: × 

35, 00: LST x 

35, 07: x<>y 

35, 09: R↑ 

35, 07: x<>y 

51: - 

35, 09: R↑ 

81: ÷ 

41: ENTER 

35, 08: R↓ 

51: - 

35, 09: R↑ 

35, 07: x<>y 

24: RTN

Example 1: 

(12*w + 28) ÷ ((w+2) * (w+3)) = 4 ÷ (w+2) + 8 ÷ (w+3) 

Input Stack: T: 12, Z: 28, Y: 2, X: 3 press [ A ] 

Output Stack: Y (B): 4, X (A): 8

Example 2: 

(33) ÷ ((w-5) * (w+6)) = 3 ÷ (w-5) + -3 ÷ (w+6) 

Input Stack: T: 0, Z: 33, Y: -5, X: 6 press [ A ] 

Output Stack: Y (B): 3, X (A): -3

Example 3: 

(2*w - 3) ÷ ((w-1) * (w+4)) = -0.2 ÷ (w-1) + 0.2 ÷ (w+4) 

Input Stack: T: 2, Z: -3, Y: -1, X: 4 press [ A ] 

Output Stack: Y (B): -0.2, X (A): 0.2

Eddie

All original content copyright, © 2011-2026. Edward Shore. Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited. This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.

TI-84 Plus CE, HP 15C, and HP 12C: Decoding the Gradematic 100

TI-84 Plus CE, HP 15C, and HP 12C: Decoding the Gradematic 100

GPA as a function of grade

Last December, we have gave a spotlight on the Calculated Industries 100 from 1983. The Gradematic 100 was a specialty calculator that determines the GPA average for a student or a bunch of students in a class. We can either use numerical grades, where the maximum total score and the minimum passing grade (better than E (or F)) are set, or letter grades, where the letters are given an approximated. To see the review, click the link below:

https://edspi31415.blogspot.com/2025/12/spotlight-calculated-industries.html

Using the standard grade scale for a single assignment, with a perfect score being 100 and the minimum passing grade is 60, the following scores are given the GPA:

GRADE (0 – 100)	GPA	Letter Grade Given by Gradematic 100
0	0.00	E (can stand for F)
10	0.08	E (can stand for F)
20	0.16	E (can stand for F)
30	0.25	E (can stand for F)
40	0.33	E (can stand for F)
50	0.41	E (can stand for F)
55	0.45	E (can stand for F)
60	0.50	D-
65	1.00	D
70	1.50	C-
75	2.00	C
80	2.50	B-
85	3.00	B
90	3.50	A-
95	4.00	A
100	4.50	A+

Plot of values (using a TI-84 Plus CE):

As we can see, the plot consists of two line segments: one where grades value from 0 to 60, and one where grades value from 60 and higher. It is apparent that that the two parts makes a piece-wise function consisting of two lines.

Note: the graphs and statistics were done with the TI-84 Plus CE Python (will work with any TI-84 CE family). The piecewise function is from the math-math menu.

The Gradematic 100 distributes the GPA as:

E: 0.00 (or F)	D+: 1.33	C+: 2.33	B+: 3.33	A+: 4.33
D-: 0.66	C-: 1.66	B-: 2.66	A-: 3.66
D: 1.00	C: 2.00	B: 3.00	A: 4.00

Note: The distributed GPA scales will vary among the school districts and systems. However, we will assume the system that matches the default 60/100 system.

HP 15C and HP 12C: Find the GPA given numeric grade

HP 15C Code:

LBL C	001	42, 21, 13
6	002	6
0	003	0
x≤y	004	43, 10
GTO 1	005	22, 1
2	006	2
×	007	20
÷	008	10
RTN	009	43, 32
LBL 1	010	42, 21, 1
CL x	011	43, 35
1	012	1
0	013	0
÷	014	10
5	015	5
.	016	48
5	017	5
-	018	30
RTN	019	43, 32

HP 12C Code:

6	01	6
0	02	0
x≤y	03	43, 34
GTO 09	04	43, 33, 09
2	05	2
×	06	20
÷	07	10
GTO 00	08	43, 33, 00
CL x	09	35
1	10	1
0	11	0
÷	12	10
5	13	5
.	14	48
5	15	5
-	16	30
GTO 00	17	43, 33, 00

Eddie

All original content copyright, © 2011-2026. Edward Shore. Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited. This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.