Casio Fx 3650P II 3650PII EN

User Manual: Casio fx-3650PII fx-3650P II | Calculators | Manuals | CASIO

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fx-3650P

II

User's Guide

CASIO Worldwide Education Website

http://edu.casio.com

CASIO EDUCATIONAL FORUM

http://edu.casio.com/forum/

RJA527880-001V01

E

E-1

Getting Started

Thank you for purchasing this CASIO product.

k Before using the calculator for the first time...

Before using the calculator, slide its hard case

downwards to remove it, and then affix the hard

case to the back of the calculator as shown in the

illustration nearby.

A After you are finished using the calculator...

Remove the hard case from the back of the calculator, and re-install it onto the front.

k Resetting the Calculator to Initial Defaults

Perform the operation below when you want to return the calculator’s setup to its initial

defaults. Note that this procedure will also clear all memory contents (independent memory,

variable memory, Answer Memory, statistical calculation sample data, and program data).

!9(CLR)

3(All)

w

k About this Manual

• The displays and illustrations (such as key markings) shown in this User’s Guide are for

illustrative purposes only, and may differ somewhat from the actual items they represent.

• The contents of this manual are subject to change without notice.

• In no event shall CASIO Computer Co., Ltd. be liable to anyone for special, collateral,

incidental, or consequential damages in connection with or arising out of the purchase or

use of this product and items that come with it. Moreover, CASIO Computer Co., Ltd. shall

not be liable for any claim of any kind whatsoever by any other party arising out of the use

of this product and the items that come with it.

Safety Precautions

Battery

• Keep batteries out of the reach of small children.

• Use only the type of battery specified for this calculator in this manual.

E-2

Operating Precautions

• Even if the calculator is operating normally, replace the battery at least once every

three years (LR44 (GPA76)).

A dead battery can leak, causing damage to and malfunction of the calculator. Never

leave a dead battery in the calculator. Do not try using the calculator while the battery is

completely dead.

• The battery that comes with the calculator discharges slightly during shipment

and storage. Because of this, it may require replacement sooner than the normal

expected battery life.

• Do not use an oxyride battery* or any other type of nickel-based primary

battery with this product. Incompatibility between such batteries and product

specifications can result in shorter battery life and product malfunction.

• Low battery power can cause memory contents to become corrupted or lost

completely. Always keep written records of all important data.

• Avoid use and storage of the calculator in areas subjected to temperature

extremes, and large amounts of humidity and dust.

• Do not subject the calculator to excessive impact, pressure, or bending.

• Never try to take the calculator apart.

• Use a soft, dry cloth to clean the exterior of the calculator.

• Whenever discarding the calculator or batteries, be sure to do so in accordance

with the laws and regulations in your particular area.

• Be sure to keep all user documentation handy for future reference.

* Company and product names used in this manual may be registered trademarks or

trademarks of their respective owners.

E-3

π

Contents

Getting Started ..........................................................................................1

Safety Precautions ...................................................................................1

Operating Precautions .............................................................................2

Before starting a calculation... ................................................................4

Calculation Modes and Setup .................................................................5

Inputting Calculation Expressions and Values ......................................7

Basic Calculations .................................................................................. 11

Calculation History and Replay .............................................................13

Calculator Memory Operations .............................................................14

Scientifi c Function Calculations ..........................................................17

Using 103 Engineering Notation (ENG) .................................................25

Complex Number Calculations (CMPLX) .............................................25

Statistical Calculations (SD/REG) .........................................................29

Base-n Calculations (BASE) ..................................................................40

Program Mode (PRGM) ..........................................................................43

Appendix .................................................................................................53

Power Requirements ..............................................................................57

Specifi cations .........................................................................................58

E-4

Before starting a calculation...

k Turning On the Calculator

Press

O. The calculator will enter the calculation mode (page 5) that it was in the last time

you turned it off.

A

Adjusting Display Contrast

If the figures on the display become hard to read, try adjusting display contrast.

1. Press

!N(SETUP)

db(Contrast).

• This will display the contrast adjustment screen.

2. Use

d and

e to adjust display contrast.

3. After the setting is the way you want, press

A or

!p(EXIT).

Note

You can also use

+ and

- to adjust contrast while the calculation mode menu that

appears when you press the

, key is on the display.

Important!

If adjusting display contrast does not improve display readability, it probably means that

battery power is low. Replace the battery.

A

Turning Off the Calculator

Press

!A(OFF).

The following information is retained when you turn off the calculator.

• Calculation modes and setup (page 5)

• Answer Memory (page 14), independent memory (page 15), and variable memory (page

16) contents

k Key Markings

M–

M

DT CL

ALOGIC

x

!

8

Function Colors To perform the function

1M+ Press the key.

2M– Text: Amber Press ! and then press the key.

3M Text: Red Press a and then press the key.

4DT Text: Blue In the SD or REG Mode, press the key.

5CL Text: Amber

Frame: Blue

In the SD or REG Mode, press ! and then press

the key.

6 ∠ Text: Amber

Frame: Purple

In the CMPLX Mode, press ! and then press the

key.

L I GHT DARK

CASIO

E-5

Function Colors To perform the function

7A Text: Red

Frame: Green

Press a and then press the key (variable A).

In the BASE Mode, press the key.

8LOGIC Text: Green In the BASE Mode, press the key.

k Reading the Display

A

Input Expressions and Calculation Results

This calculator can display both the expressions you input and calculation results on the

same screen.

Input expression

Calculation result

A

Display Symbols

The symbols described below appear on the display of the calculator to indicate the current

calculation mode, the calculator setup, the progress of calculations, and more. In this

manual, the expression “turn on” is used to mean that a symbol appears on the display, and

“turn off” means that it disappears.

The nearby sample screen shows the

7

symbol.

Calculation Modes and Setup

k Selecting a Calculation Mode

Your calculator has six “calculation modes”.

1. Press

,.

• This displays the calculation mode menu.

• The calculation mode menu has two screens. Press

, to toggle between them. You

can also switch between menu screens using

d and

e.

COMP CMPLX BASE

1 2 3

SD REG PRGM

4 5 6

2. Perform one of the following operations to select the calculation mode you want.

b (COMP): COMP(Computation) c (CMPLX): CMPLX (Complex Number)

d (BASE): BASE (Base n ) e (SD): SD (Single Variable Statistics)

f (REG): REG (Paired Variable Statistics) g (PRGM): PRGM (Program)

• Pressing a number key from b to g selects the applicable mode, regardless of which

menu screen is currently displayed.

2×

(

5+4

)

–2×-3

24

E-6

k Calculator Setup

The calculator setup can be used to configure input and output settings, calculation

parameters, and other settings. The setup can be configured using setup screens, which

you access by pressing

!,(SETUP). There are six setup screens, and you can use

d and

e to navigate between them.

A

Specifying the Angle Unit

90˚ =

π

2 radians = 100 grads

Angle Unit Perform this key operation:

Degrees !,

b (Deg)

Radians !,

c (Rad)

Grads !,

d (Gra)

A

Specifying the Display Digits

Exponential Display Perform this key operation:

Number of Decimal Places !,

e

b (Fix)a (0) to j (9)

Significant Digits !,

e

c (Sci)b (1) to j (9), a (10)

Exponential Display Range !,

e

d (Norm)b (Norm1) or c (Norm2)

The following explains how calculation results are displayed in accordance with the setting

you specify.

• From zero to nine decimal places are displayed in accordance with the number of decimal

places (Fix) you specify. Calculation results are rounded off to the specified number of

digits.

Example: 100 ÷ 7 = 14.286 (Fix = 3)

• After you specify the number of significant digits with Sci, calculation results are displayed

using the specified number of significant digits and 10 digits to the applicable power.

Calculation results are rounded off to the specified number of digits.

Example: 1 ÷ 7 = 1.4286 × 10

–1

(Sci = 5)

• Selecting Norm1 or Norm2 causes the display to switch to exponential notation whenever

the result is within the ranges defined below.

Norm1: 10

–2

>

 x



,

 x 

> 10

10

Norm2: 10

–9

>

 x 

,

 x 

> 10

10

Example: 1 ÷ 200 = 5. × 10

–3

(Norm1) 0.005 (Norm2)

A

Specifying the Fraction Display Format

Fraction Format Perform this key operation:

Mixed Fractions !,

ee

b (ab/c)

Improper Fractions !,

ee

c (d/c)

E-7

A

Specifying the Complex Number Display Format

Complex Number Format Perform this key operation:

Rectangular Coordinates !,

eee

b ( a + b

i )

Polar Coordinates !,

eee

c ( r

∠

 )

A

Specifying the Statistical Frequency Setting

Frequency Setting Perform this key operation:

Frequency On !,

dd

b (FreqOn)

Frequency Off !,

dd

c (FreqOff)

k Clearing the Calculation Mode and Setup Settings

Perform the procedure described below to clear the current calculation mode and all setup

settings and initialize the calculator to the following.

Calculation Mode ................................COMP (Computation Mode)

Angle Unit ...........................................Deg (Degrees)

Exponential Display ............................. Norm1

Fraction Format .................................. ab/c (Mixed Fractions)

Complex Number Format ...................

a

+

b i

(Rectangular Coordinates)

Frequency Setting ..............................FreqOn (Frequency On)

Perform the following key operation to clear the calculation mode and setup settings.

!9(CLR)

2(Setup)

w

If you do not want to clear the calculator’s settings, press

A in place of

w in the above

operation .

Inputting Calculation Expressions

and Values

k Inputting a Calculation Expression

Your calculator lets you input a calculation expression just as it is written and execute

it by pressing

w. The calculator determines the proper priority sequence for addition,

subtraction, multiplication, division, functions and parentheses automatically.

Example: 2 × (5 + 4) – 2 × (–3) =

2*(5+4)-

2*-3w

2×

(

5+4

)

–2×-3

24

E-8

A

Inputting Scientific Functions with Parentheses (sin, cos,

',

etc.)

Your calculator supports input of the scientific functions with parentheses shown below.

Note that after you input the argument, you need to press ) to close the parentheses.

sin(, cos(, tan(, sin –1 (, cos –1 (, tan –1 (, sinh(, cosh(, tanh(, sinh –1 (, cosh –1 (, tanh –1 (, log(, ln(,

e ^(, 10^(, ' (, 3

' (, Abs(, Pol(, Rec(, arg(, Conjg(, Not(, Neg(, Rnd(, ∫(, d/dx(

Example: sin 30 =

s30)w

A Omitting the Multiplication Sign

You can omit the multiplication sign in the following cases.

• Immediately before an open parenthesis: 2 × (5 + 4)

• Immediately before a scientific function with parentheses: 2 × sin(30), 2 ×

'(3)

• Before a prefix symbol (excluding the minus sign): 2 × h123

• Before a variable name, constant, or random number: 20 × A, 2 ×

π

Important!

If you execute a calculation that includes both division and multiplication operations in which

a multiplication sign has been omitted, parentheses will be inserted automatically as shown

in the examples below.

• When a multiplication sign is omitted immediately before an open parenthesis or after a

closed parenthesis.

6 ÷ 2 (1 + 2) p 6 ÷ (2 (1 + 2)) 6 ÷ A (1 + 2) p 6 ÷ (A (1 + 2))

1 ÷ (2 + 3) sin(30) p 1 ÷ ((2 + 3) sin(30))

• When a multiplication sign is omitted immediately before a variable, a constant, etc.

6 ÷ 2π p 6 ÷ (2π) 2 ÷ 2'

(2) p 2 ÷ (2'(2)) 4π ÷ 2π p 4π ÷ (2π)

• When inputting a function that uses commas (such as Pol, Rec), be sure to input the

closed parentheses required by the expression. If you do not input closed parentheses,

parentheses may not be inserted automatically as described above.

A

Final Closed Parenthesis

You can omit one or more closed parentheses that come at the end of a calculation,

immediately before the

w key is pressed.

Example: (2 + 3) × (4 – 1) = 15

(2+3)*

(4-1w

A

Scrolling the Screen Left and Right

Input Expression 12345 + 12345 + 12345

Displayed Expression

Cursor

sin

(

30

)

05

(

2+3

)

×

(

4–1

15

345+12345+12345I

E-9

• While the

b

symbol is on the screen, you can use the

d key to move the cursor to the

left and scroll the screen.

• Scrolling to the left causes part of the expression to run off the right side of the display,

which is indicated by the

\

symbol on the right. While the

\

symbol is on the screen,

you can use the

e key to move the cursor to the right and scroll the screen.

• You can also press

f to jump to the beginning of the expression, or

c to jump to the

end.

A

Number of Input Characters (Bytes)

As you input a mathematical expression, it is stored in memory called an “input area,”

which has a capacity of 99 bytes. This means you can input up to 99 bytes for a single

mathematical expression.

Normally, the cursor that indicates the current input location on the display is either a

flashing vertical bar (

|

) or horizontal bar (

). When the remaining capacity of the input area

is 10 bytes or less, the cursor changes to a flashing box (

k

).

If this happens, stop input of the current expression at some suitable location and calculate

its result.

k Editing a Calculation

A

Insert Mode and Overwrite Mode

The calculator has two input modes. The insert mode inserts your input at the cursor

location, shifting anything to the right of the cursor to make room. The overwrite mode

replaces the key operation at the cursor location with your input.

Original Expression Pressing +

Insert Mode 1+2

|

34

Cursor

1+2+

|

34

Overwrite Mode

1+2 3 4

Cursor

1+2 + 4

The initial default input mode setting is insert mode.

To change to the overwrite mode, press:

1D(INS).

A

Editing a Key Operation You Just Input

Example: To correct 369 × 13 so it becomes 369 × 12

369*13

D2

369×13I

369×12I

E-10

A

Deleting a Key Operation

Example: To correct 369 × × 12 so it becomes 369 × 12

Insert Mode

369**12

ddD

Overwrite Mode

369**12

dddD

A

Editing a Key Operation within an Expression

With the insert mode, use

d and

e to move the cursor to the right of the key operation

you want to edit, press

D to delete it, and then perform the correct key operation. With the

overwrite mode, move the cursor to the key operation you want to correct and then perform

the correct key operation.

A

Inserting Key Operations into an Expression

Be sure to select the insert mode whenever you want to insert key operations into an

expression. Use

d and

e to move the cursor to the location where you want to insert

the key operations, and then perform them.

k Finding the Location of an Error

If your calculation expression is incorrect, an error message will appear on the display when

you press

w to execute it. After an error message appears, press the

d or

e key

and the cursor will jump to the location in your calculation that caused the error so you can

correct it.

Example: When you input 14 ÷ 0 × 2 = instead of 14 ÷ 10 × 2 =

(The following examples use the insert mode.)

14/0*2w

e or

d

Location of Error

d1w

369××12I

369×I12

369××12

369×12

Mat h ERROR

14÷0I×2

14÷10×2

28

E-11

Basic Calculations

Unless otherwise noted, the calculations in this section can be performed in any of the

calculator’s calculation mode, except for the BASE Mode.

k Arithmetic Calculations

Arithmetic calculations can be used to perform addition (

+), subtraction (

-),

multiplication (

*), and division (

/).

Example: 7 × 8 − 4 × 5 = 36

7*8-4*5w

k Fractions

Fractions are input using a special separator symbol (

{).

A

Fraction Calculation Examples

Example 1: 3

1

4

+ 1

2

3

= 4

1 1

1 2 3$1$4+

1$2$3w

Example 2:

2

3

+

1

2

=

7

6

(Fraction Display Format: d/c)

2$3+1$2w

Note

• If the total number of elements (integer + numerator + denominator + separator symbols)

of a fraction calculation result is greater than 10 digits, the result will be displayed in

decimal format.

• If an input calculation includes a mixture of fraction and decimal values, the result will be

displayed in decimal format.

• You can input integers only for the elements of a fraction. Inputting non-integers will

produce a decimal format result.

A

Switching between Mixed Fraction and Improper Fraction

Format

To convert a mixed fraction to an improper fraction (or an improper fraction to a mixed

fraction), press

!$(d/c).

A

Switching between Decimal and Fraction Format

Press $ to toggle between decimal value and fraction display format.

Note

The calculator cannot switch from decimal to fraction format if the total number of fraction

elements (integer + numerator + denominator + separator symbols) is greater than 10 digits.

36

4

{

11

{

12

7

{

6

E-12

k Percent Calculations

Inputting a value and with a percent (%) sign makes the value a percent.

A

Percent Calculation Examples

Example 1: 2 % = 0.02 (

2

1 0 0

)

2!((%)

w

Example 2: 150 × 20% = 30 (150 × 20

100 )

150*20

!((%)

w

Example 3: What percent of 880 is 660?

660/880

!((%)

w

Example 4: Increase 2,500 by 15%.

2500+2500*

15!((%)

w

Example 5: Reduce 3,500 by 25%.

3500-3500*

25!((%)

w

Example 6: Reduce the sum of 168, 98, and 734 by 20%.

168+98+734w

-G*20!((%)

w

Example 7: 300 grams are added to a test sample originally weighing 500 grams,

producing a final test sample of 800 grams. What percent of 500 grams is 800

grams?

(500+300)

/500!((%)

w

Example 8: What is the percentage change when a value is increased from 40 to 46?

(46-40)/40

!((%)w

002

30

75

2875

2625

1000

800

160

15

E-13

k Degree, Minute, Second (Sexagesimal) Calculations

A

Inputting Sexagesimal Values

The following is basic syntax for inputting a sexagesimal value.

{Degrees}

$ {Minutes}

$ {Seconds}

$

Example: To input 2°30´30˝

2$30$30$w

• Note that you must always input something for the degrees and minutes, even if they are

zero.

A

Sexagesimal Calculation Examples

The following types of sexagesimal calculations will produce sexagesimal results.

• Addition or subtraction of two sexagesimal values

• Multiplication or division of a sexagesimal value and a decimal value

Example: 2°20´30˝ + 39´30˝ = 3°00´00˝

2$20$30$+

0$39$30$w

A

Converting between Sexagesimal and Decimal

Pressing

$ while a calculation result is displayed will toggle the value between

sexagesimal and decimal.

Example: To convert 2.255 to sexagesimal

2.255w$

Calculation History and Replay

Calculation history maintains a record of each calculation you perform, including the

expressions you input and calculation results. You can use calculation history in the COMP,

CMPLX, and BASE Modes.

k Accessing Calculation History

The

` symbol in the upper right corner of the display indicates that there is data stored in

calculation history. To view the data in calculation history, press

f. Each press of

f

will scroll upwards (back) one calculation, displaying both the calculation expression and its

result.

Example: 1+1w2+2w3+3w

2˚30˚30˚

2˚30˚30

3˚0˚0

2˚15˚18

3+3

6

2+2

4

1+1

2

ff

E-14

While scrolling through calculation history records, the $ symbol will appear on the display,

which indicates that there are records below (newer than) the current one. When this

symbol is turned on, press c to scroll downwards (forward) through calculation history

records.

Important!

• Calculation history records are all cleared whenever you press p, when you change to a

different calculation mode, and whenever you perform any reset operation.

• Calculation history capacity is limited. Whenever you perform a new calculation while

calculation history is full, the oldest record in calculation history is deleted automatically to

make room for the new one.

k Using Replay

While a calculation history record is on the display, press

d or

e to display the cursor

and enter the editing mode. Pressing

e displays the cursor at the beginning of the

calculation expression, while

d displays it at the end. After you make the changes you

want, press

w to execute the calculation.

Example: 4 × 3 + 2.5 = 14.5

4 × 3 – 7.1 = 4.9

4*3+2.5w

d

DDDD-7.1w

Calculator Memory Operations

k Using Answer Memory (Ans)

The result of any new calculation you perform on the calculator is stored automatically in

Answer Memory (Ans).

A

Ans Update and Delete Timing

When using Ans in a calculation, it is important to keep in mind how and when its contents

change. Note the following points.

• The contents of Ans are replaced whenever you perform any of the following operations:

calculate a calculation result, add a value to or subtract a value from independent

memory, assign a value to a variable or recall the value of a variable, or input statistical

data in the SD Mode or REG Mode.

• In the case of a calculation that produces more than one result (like coordinate

calculations), the value that appears first on the display is stored in Ans.

• The contents of Ans do not change if the current calculation produces an error.

4×3+2.5

145

4×3+2.5I

4×3–7.1

49

E-15

• When you perform a complex number calculation in the CMPLX Mode, both the real part

and the imaginary part of the result are stored in Ans. Note, however, that the imaginary

part of the value is cleared if you change to another calculation mode.

A

Automatic Insertion of Ans in Consecutive Calculations

Example: To divide the result of 3 × 4 by 30

3*4w

(Next) /30w

Pressing

/ inputs Ans automatically.

Note

In the case of a function with parenthetical argument (page 8), Ans automatically becomes

the argument only in the case that you input the function alone and then press w.

A

Inserting Ans into a Calculation Manually

Example: To use the result of 123 + 456 in another calculation as shown below

123 + 456 = 579 789 – 579 = 210

123+456w

789-Kw

k Using Independent Memory

Independent memory (M) is used mainly for calculating cumulative totals.

If you can see the M symbol on the display, it means there is a non-zero value in

independent memory. Independent memory can be used in all calculation modes, except

for the SD Mode and the REG Mode.

M symbol

A

Adding to Independent Memory

While a value you input or the result of a calculation is on the display, press

m to add it to

independent memory (M).

Example: To add the result of 105 ÷ 3 to independent memory (M)

105/3m

12

Ans÷30

04

579

210

10M+

35

E-16

A Subtracting from Independent Memory

While a value you input or the result of a calculation is on the display, press

1m(M–) to

subtract it from independent memory (M).

Example: To subtract the result of 3 × 2 from independent memory (M)

3*21m(M–)

Note

Pressing

m or

1m(M–) while a calculation result is on the display will add it to or

subtract it from independent memory.

Important!

The value that appears on the display when you press

m or

1m(M–) at the end of a

calculation in place of

w is the result of the calculation (which is added to or subtracted

from independent memory). It is not the current contents of independent memory.

A

Viewing Independent Memory Contents

Press tm(M).

A

Clearing Independent Memory Contents (to 0)

01t(STO)m(M)

Clearing independent memory will cause the M symbol to turn off.

k Using Variables

The calculator supports six variables named A, B, C, D, X, and Y, which you can use to

store values as required. Variables can be used in all calculation modes.

A

Assigning a Value or Calculation Result to a Variable

Use the procedure shown below to assign a value or a calculation expression to a variable.

Example: To assign 3 + 5 to variable A 3+51t(STO)-(A)

A

Viewing the Value Assigned to a Variable

To view the value assigned to a variable, press

t and then specify the variable name.

Example: To view the value assigned to variable A t-(A)

A

Using a Variable in a Calculation

You can use variables in calculations the same way you use values.

Example: To calculate 5 + A 5+a-(A)w

A

Clearing the Value Assigned to a Variable (to 0)

Example: To clear variable A 01t(STO)-(A)

6

E-17

k Clearing All Memory Contents

Perform the following key operation when you want to clear the contents of independent

memory, variable memory, and Answer Memory.

19(CLR)1(Mem)w

• If you do not want to clear the calculator’s settings, press A in place of w in the above

operation.

Scientific Function Calculations

Unless otherwise noted, the functions in this section can be used in any of the calculator’s

calculation modes, except for the BASE Mode.

Scientific Function Calculation Precautions

• When performing a calculation that includes a built-in scientific function, it may take some

time before the calculation result appears. Do not perform any key operation on the

calculator until the calculation result appears.

• To interrupt and on-going calculation operation, press A.

Interpreting Scientific Function Syntax

• Text that represents a function’s argument is enclosed in braces ({ }). Arguments are

normally {value} or {expression}.

• When braces ({ }) are enclosed within parentheses, it means that input of everything

inside the parentheses is mandatory.

k Pi (

π

) and Natural Logarithm Base e

The calculator supports input of pi (π) and natural logarithm base e into calculations. π and

e are supported in all modes, except for the BASE Mode. The following are the values that

the calculator applies for each of the built-in constants.

π = 3.14159265358980 (1e(π))

e = 2.71828182845904 (Si(e))

k Trigonometric and Inverse Trigonometric Functions

A

Syntax and Input

sin( {

n

}), cos( {

n

}), tan( {

n

}), sin

–1

({

n

}), cos

–1

({

n

}), tan

–1

({

n

})

Example: sin 30 = 0.5, sin

–1

0.5 = 30 (Angle Unit: Deg)

s30)w

1s(sin

–1

)

0.5)w

05

30

E-18

A

Notes

• These functions can be used in the CMPLX Mode, as long as a complex number is not

used in the argument. A calculation like

i × sin(30) is supported for example, but sin(1 +

i

)

is not.

• The angle unit you need to use in a calculation is the one that is currently selected as the

default angle unit.

k Angle Unit Conversion

You can convert a value that was input using one angle unit to another angle unit.

After you input a value, press

1G(DRG

') to display the menu screen shown below.

1(D): Degrees

2( R

): Radians

3( G

): Grads

Example: To convert

π

2 radians to degrees (Angle Unit: Deg)

(1e(

π )

/2)

1G(DRG

')

2( R

)

E

k Hyperbolic and Inverse Hyperbolic Functions

A

Syntax and Input

sinh({

n

}), cosh( {

n

}), tanh( {

n

}), sinh

–1

({

n

}), cosh

–1

({

n

}), tanh

–1

({

n

})

Example: sinh 1 = 1.175201194

ws(sinh)

1)E

A

Notes

• After pressing

w to specify a hyperbolic function or

1w to specify an inverse

hyperbolic function, press

s,

c, or

t.

• These functions can be used in the CMPLX Mode, but complex number arguments are

not supported.

k Exponential and Logarithmic Functions

A

Syntax and Input

10^( {

n

}) .......................... 10

{

n }

e^({

n

}) ............................. e{

n }

log( {

n

}) ........................... log

10

{

n

} (Common Logarithm)

log( {

m

},{

n

}) ..................... log

{

m }

{

n

} (Base {

m

} Logarithm)

ln( {

n

}) ............................. log

e

{

n

} (Natural Logarithm)

DRG

312

(

π

÷2

)

r

90

1175201194

E-19

Example 1: log

2

16 = 4, log16 = 1.204119983

l2,16)E

l16)E

Base 10 (common logarithm) is assumed when no base is specified.

Example 2: ln 90 (log

e

90) = 4.49980967

I90)E

k Power Functions and Power Root Functions

A

Syntax and Input

{

n

}

x 2

............................... {

n

}

2

(Square)

{

n

}

x 3

............................... {

n

}

3

(Cube)

{

n

}

x –1

............................. {

n

}

–1

(Reciprocal)

{(

m

)} ^( {

n

}) ....................... { m

}

{

n }

(Power)

'({

n

}) .......................... {

n

} (Square Root)

3

'({

n

}) .........................

3

{

n

} (Cube Root)

({

m

})

x '({

n

}) ..................

{

m }

{

n

} (Power Root)

Example 1: (

'

2 + 1) (

'

2 – 1) = 1

(92)+1)

(92)-1)E

Example 2: –2

2

3 = –1.587401052

-2M2$3)E

A

Notes

• The functions

x 2

,

x 3

, and

x –1

can be used in complex number calculations in the CMPLX

Mode. Complex number arguments are also supported for these functions.

• ^(,

'(,

3

'(,

x '( are also supported in the CMPLX Mode, but complex number

arguments are not supported for these functions.

4

lo

g(

16

)

1204119983

449980967

(

'

(

2

)

+1

)(

'

(

2

)

–1

)

1

–2

ˆ

(

2{3

)

-

1587401052

E-20

k Coordinate Conversion (Rectangular

↔

Polar)

Your calculator can convert between rectangular coordinates and polar coordinates.

o

o

Rectangular Coordinates (Rec) Polar Coordinates (Pol)

A

Syntax and Input

Rectangular-to-Polar Coordinate Conversion (Pol)

Pol(

x

,

y

)

x : Rectangular coordinate

x

-value

y

: Rectangular coordinate

y

-value

Polar-to-Rectangular Coordinate Conversion (Rec)

Rec(

r

,



)

r : Polar coordinate

r

-value



: Polar coordinate



-value

Example 1: To convert the rectangular coordinates (

'

2,

'

2 ) to polar coordinates

(Angle Unit: Deg) 1+(Pol)

92)

,92))E

(View the value of



)

t,(Y)

Example 2: To convert the polar coordinates (2, 30°) to rectangular coordinates

(Angle Unit: Deg) 1-(Rec)

2,

30)E

(View the value of

y

)

t,(Y)

A

Notes

• These functions can be used in the COMP, SD, and REG Modes.

• Calculation results show the first

r

value or

x

value only.

• The

r

-value (or

x

-value) produced by the calculation is assigned to variable X, while the



-value (or

y

-value) is assigned to variable Y (page 16). To view the



-value (or

y

-value),

display the value assigned to variable Y, as shown in the example.

• The values obtained for



when converting from rectangular coordinates to polar

coordinates is within the range –180°<



< 180°.

2

45

1732050808

1

E-21

• When executing a coordinate conversion function inside of a calculation expression, the

calculation is performed using the first value produced by the conversion (

r

-value or

x

-

value).

Example: Pol (

'

2,

'

2 ) + 5 = 2 + 5 = 7

k Integration Calculation and Differential Calculation

A

Integration Calculation

Your calculator performs integration using the Gauss-Kronrod method.

Syntax and Input

∫

( f

(x), a, b, tol)

f

(x): Function of X (Input the function used by variable X.)

a: Lower limit of region of integration

b: Upper limit of region of integration

tol: Error tolerance range

• This parameter can be omitted. In that case, a tolerance of 1 × 10–5 is used.

Example: In(x)=1

1

∫e

fIa0(X)),1,aI(e))E

A Differential Calculation

Your calculator approximates the derivative based on the central difference method.

Syntax and Input

d/dx( f

(x), a, tol)

f

(x): Function of X (Input the function used by variable X.)

a: Input value of point (differential point) of desired differential coefficient

tol: Error tolerance range

• This parameter can be omitted. In that case, a tolerance of 1 × 10–10 is used.

Example: To obtain the derivative at point x = π

2 for the function y = sin(x) (Angle Unit: Rad)

1f(d/dx)sa0(X)),

1e(π)/2)E

A Integration and Differential Calculation Precautions

• Integration and differential calculations can be performed in the COMP Mode and PRGM

Mode (run mode: COMP) only.

• The following cannot be used in f(x): Pol, Rec. The following cannot be used in f(x), a, b,

or tol: ∫, d/dx.

• When using a trigonometric function in f(x), specify Rad as the angle unit.

∫

(

In

(

X

)

,1,e

)

1

d/ dx

(

sin

(

X

)

,

π

÷2

)

0

E-22

• A smaller tol value increases precision, but it also increases calculation time. When

specifying tol, use value that is 1 × 10–14 or greater.

Precautions for Integration Calculation Only

• Integration normally requires considerable time to perform.

• For f(x)  0 where a  x b (as in the case of ∫0

1 3x2 – 2 = –1), calculation will produce a

negative result.

• Depending on the content of f(x) and the region of integration, calculation error that

exceeds the tolerance may be generated, causing the calculator to display an error

message.

Precautions for Differential Calculation Only

• If convergence to a solution cannot be found when tol input is omitted, the tol value will

be adjusted automatically to determine the solution.

• Non-consecutive points, abrupt fluctuation, extremely large or small points, inflection

points, and the inclusion of points that cannot be differentiated, or a differential point or

differential calculation result that approaches zero can cause poor precision or error.

A Tips for Successful Integration Calculations

When a periodic function or integration interval results in positive

and negative f(x) function values

Perform separate integrations for each cycle, or for the positive part and the negative part,

and then combine the results.

When integration values fluctuate widely due to minute shifts in the

integration interval

Divide the integration interval into multiple parts (in a way that breaks areas of wide

fluctuation into small parts), perform integration on each part, and then combine the results.

S Positive

S Negative

∫∫

a

c f(x)dx + (– c

b f(x)dx)

Positive Part

(S Positive)

Negative Part

(S Negative)

b

ax1x2x3x4

x

0

f (x)

a

b f(x)dx = a

x1

f(x)dx + x1

x2

f(x)dx +.....

∫∫∫

x4

b

f(x)dx

∫

+

E-23

k Other Functions

x !, Abs(, Ran#, n P r , n C r , Rnd(

The

x

!,

n

P

r

, and

n

C

r

functions can be used in the CMPLX Mode, but complex number

arguments are not supported.

A

Factorial (!)

Syntax: {

n

} ! ({

n

} must be a natural number or 0.)

Example: (5 + 3)!

(5+3)

1X(

x

!)

E

A

Absolute Value (Abs)

When you are performing a real number calculation, Abs( simply obtains the absolute value.

This function can be used in the CMPLX Mode to determine the absolute value (size) of a

complex number. See “Complex Number Calculations” on page 25 for more information.

Syntax: Abs( {

n

})

Example: Abs (2 – 7) = 5

1)(Abs)

2-7)E

A

Random Number (Ran#)

This function generates a three-decimal place (0.000 to 0.999) pseudo random number. It

does not require an argument, and can be used the same way as a variable.

Syntax: Ran#

Example: To use 1000Ran# to obtain three 3-digit random numbers.

10001.(Ran#)

E

E

E

• The above values are provided for example only. The actual values produced by your

calculator for this function will be different.

40320

5

287

613

118

E-24

A

Permutation (

n

P

r

)/Combination (

n

C

r

)

Syntax: {

n

}P{

m

}, {

n

}C{

m

}

Example: How many four-person permutations and combinations are possible for a group

of 10 people?

101*(

n

P

r

)

4E

101/(

n

C

r

)

4E

A

Rounding Function (Rnd)

You can use the rounding function (Rnd) to round the value, expression, or calculation

result specified by the argument. Rounding is performed to the number of significant digits

in accordance with the number of display digits setting.

Rounding for Norm1 or Norm2

The mantissa is rounded off to 10 digits.

Rounding for Fix or Sci

The value is rounded to the specified number of digits.

Example: 200 ÷ 7 × 14 = 400

(3 decimal places) 1Ne1(Fix)

3

(Internal calculation uses 15 digits.) 200/7E

*14E

Now perform the same calculation using the rounding (Rnd) function.

200/7E

(Calculation uses rounded value.) 10(Rnd)

E

(Rounded result) *14E

5040

210

28571

400000

28571

399994

E-25

Using 10

3

Engineering Notation (ENG)

Engineering notation (ENG) expresses quantities as a product of a positive number

between 1 and 10 and a power of 10 that is always a multiple of three. There are two types

of engineering notation, ENG

/

and ENG

,

.

The CMPLX Mode does not support use of engineering notation.

k ENG Calculation Examples

Example 1: To convert 1234 to engineering notation using ENG

/

1234E

W

W

Example 2: To convert 123 to engineering notation using ENG

,

123E

1W(

,

)

1W(

,

)

Complex Number Calculations

(CMPLX)

To perform the example operations in this section, first select CMPLX as the calculation

mode.

k Inputting Complex Numbers

A

Inputting Imaginary Numbers (

i

)

Example: To input 2 + 3

i

2+3W(

i

)

1234

1234

03

1234

00

123

0123

03

0000123

06

2+3iI

E-26

A

Inputting Complex Number Values Using Polar Coordinate

Format

Example: To input 5

∠

30

51-(

∠

)

30

Important!

When inputting argument



, enter a value that indicates an angle in accordance with the

calculator’s current default angle unit setting.

k Complex Number Calculation Result Display

When a calculation produces a complex number result, R

⇔ I

symbol turns on in the upper

right corner of the display and the only the real part appears at first. To toggle the display

between the real part and the imaginary part, press

1E(Re

⇔

Im).

Example: To input 2 + 1

i

and display its calculation result

1,(SETUP)eee1(a

+b i

)

2+W(i

)E

Displays real part.

1E(Re

⇔

Im)

Displays imaginary part.

(

i

symbol turns on during imaginary part display. )

A

Default Complex Number Calculation Result Display Format

You can select either rectangular coordinate format or polar coordinate format for complex

number calculation results.

Imaginary axis Imaginary axis

Real axis Real axis

Rectangular Coordinates Polar Coordinates

Use the setup screens to specify the default display format you want. For details, see

“Specifying the Complex Number Display Format” (page 7).

5 30I

2+i

2

1

r

⬔



o

a

ba + bi

o

E-27

k Calculation Result Display Examples

A Rectangular Coordinate Format (a+bi)

1,(SETUP)eee1(a+bi)

Example 1: 2 × ('

3 + i) = 2'

3 + 2i = 3.464101615 + 2i

2*(93)+W(i))E

1E(Re⇔Im)

Example 2: '

2 ∠ 45 = 1 + 1i (Angle Unit: Deg)

92)1-(

∠

)

45E

1E(Re

⇔

Im)

A Polar Coordinate Format (r∠)

1,(SETUP)eee2(r∠)

Example 1: 2 × ('

3 + i) = 2'

3 + 2i = 4 ∠ 30

2*(93)+W(i))E

1E(Re⇔Im)

∠ symbol turns on during display of -value.

Example 2: 1 + 1i = 1.414213562 ∠ 45 (Angle Unit: Deg)

1+1W(i)E

1E(Re⇔Im)

k Conjugate Complex Number (Conjg)

Example: Obtain the conjugate complex number of 2 + 3i

1,(Conjg)2+3W(i))E

1E(Re⇔Im)

3464101615

2

1

1

4

30

1414213562

45

2

-

3

E-28

k Absolute Value and Argument (Abs, arg)

Example:

To obtain the absolute value and argument of 2 + 2

i

(Angle Unit: Deg)

Absolute Value: 1)(Abs)

2+2W(

i

)

)E

Argument: 1((arg)

2+2W(

i

)

)E

k Overriding the Default Complex Number Display Format

A Specifying Rectangular Coordinate Format for a Calculation

Input 1-('a+bi) at the end of the calculation.

Example: 2'

2 ∠ 45 = 2 + 2i (Angle Unit: Deg)

292)1-(∠)45

1-('a+bi)E

1E(Re⇔Im)

A Specifying Polar Coordinate Format for a Calculation

Input 1+('r∠) at the end of the calculation.

Example: 2 + 2i = 2'

2 ∠ 45 = 2.828427125 ∠ 45 (Angle Unit: Deg)

2+2W(i)

1+('r∠)E

1E(Re⇔Im)

b =

2

a =

2

o

Imaginary axis

Real axis

2828427125

45

2

2

2828427125

45

E-29

Statistical Calculations (SD/REG)

k Statistical Calculation Sample Data

A

Inputting Sample Data

You can input sample data either with statistical frequency turned on (FreqOn) or off

(FreqOff). The calculator’s initial default setting is FreqOn. You can select the input

method you want to use with the setup screen statistical frequency setting (page 7).

A Maximum Number of Input Data Items

The maximum number of data items you can input depends on whether frequency is on

(FreqOn) or off (FreqOff).

SD Mode ......40 items (FreqOn), 80 items (FreqOff)

REG Mode ...26 items (FreqOn), 40 items (FreqOff)

A Sample Data Clear

All sample data currently in memory is cleared whenever you change to another calculation

mode and when you change the statistical frequency setting.

k Performing Single-variable Statistical Calculations

To perform the example operations in this section, first select SD as the calculation mode.

A

Inputting Sample Data

Frequency On (FreqOn)

The following shows the key operations required when inputting class values

x 1

,

x 2

, ...

xn

,

and frequencies Freq1, Freq2, ... Freq

n

.

{

x 1

}

1,(;) {Freq1}

m(DT)

{

x 2

}

1,(;) {Freq2}

m(DT)

{xn}1,(;) {Freqn}m(DT)

Note

If the frequency of a class value is only one, you can input it by pressing {xn}m(DT) only

(without specifying the frequency).

Example: To input the following data: (x, Freq) = (24.5, 4), (25.5, 6), (26.5, 2)

24.51,(;)4

m(DT)

m(DT) tells the calculator this is the end of the first data item.

24

.

5

;

4I

0

Line

=

1

E-30

25.51,(;)6m(DT)

26.51,(;)2m(DT)

Frequency Off (FreqOff)

In this case, input each individual data item as shown below.

{

x 1

}

m(DT) {

x 2

}

m(DT) ... {

xn

}

m(DT)

A

Viewing Current Sample Data

After inputting sample data, you can press

c to scroll through the data in the sequence

you input it. The

$ symbol indicates there is data below the sample that is currently on the

display. The

` symbol indicates there is data above.

Example: To view the data you input in the example under “Inputting Sample Data” on

page 29 (Frequency Setting: FreqOn)

Ac

c

When the statistical frequency setting is FreqOn, data is displayed in the sequence:

x 1

,

Freq1,

x 2

, Freq2, and so on. In the case of FreqOff, it is displayed in the sequence:

x 1

,

x 2

,

x 3

, and so on. You can also use

f to scroll in the reverse direction.

A

Editing a Data Sample

To edit a data sample, recall it, input the new value(s), and then press

E.

Example: To edit the “Freq3” data sample input under “Inputting Sample Data” on page 29

Af

3E

A

Deleting a Data Sample

To delete a data sample, recall it and then press

1m(CL).

Example: To delete the “

x 2

” data sample input under “Inputting Sample Data” on page 29

Accc

Line

=

3

x 1=

245

Fre

q

1 =

4

Fre

q

3 =

2

Fre

q

3 =

3

x 2=

255

E-31

1m(CL)

Note

• The following shows images of how the data appears before and after the delete

operation.

Before After

x

1 : 24.5 Freq1: 4 x

1 : 24.5 Freq1: 4

x

2 : 25.5 Freq2: 6 x

2 : 26.5 Freq2: 2

x

3 : 26.5 Freq3: 2 Shifted upwards.

• When the statistical frequency setting is turned on (FreqOn), the applicable

x

-data and

Freq data pair is deleted.

A

Deleting All Sample Data

Perform the following key operation to delete all sample data.

19(CLR)

1(Stat)

E

If you do not want to delete all sample data, press

A in place of

E in the above operation.

A

Statistical Calculations Using Input Sample Data

To perform a statistical calculation, input the applicable command and then press E.

A SD Mode Statistical Command Reference

Line

=

2

x2 11(S-SUM)1

Obtains the sum of squares of the sample

data.

Σx2 = Σxi2

x 11(S-SUM)2

Obtains the sum of the sample data.

Σx = Σxi

n 11(S-SUM)3

Obtains the number of samples.

¯x 12(S-VAR)1

Obtains the mean.

oΣxi

n

=

σx 12(S-VAR)2

Obtains the population standard deviation.

σxn

=Σ(xi – o)2

sx 12(S-VAR)3

Obtains the sample standard deviation.

sxn – 1

=Σ(xi – o)2

minX 12(S-VAR)e1

Determines the minimum value of the

samples.

maxX 12(S-VAR)e2

Determines the maximum value of the

samples.

E-32

k Performing Paired-variable Statistical Calculations

To perform the example operations in this section, first select REG as the calculation mode.

A Regression Calculation Types

Each time you enter the REG Mode, you must select the type of regression calculation you

plan to perform.

Selecting the Regression Calculation Type

1. Enter the REG Mode.

• This displays the initial regression calculation selection menu. The menu has two

screens, and you can use d and e to navigate between them.

2. Perform one of the following operations to select the regression calculation you want.

To select this regression type: And press this key:

Linear (y = a + bx)1 (Lin)

Logarithmic (y = a + bInx)2 (Log)

e Exponential (y = aebx)3 (Exp)

Power (y = axb)4 (Pwr)

Inverse (y = a + b/x)e

1 (Inv)

Quadratic (y = a + bx + cx2)e

2 (Quad)

ab Exponential (y = abx)e

3 (AB-Exp)

Note

You can switch to another regression calculation type from within the REG Mode, if you

want. Pressing 12(S-VAR)3(TYPE) will display a menu screen like the one shown in

step 1 above. Perform the same operation as the above procedure to select the regression

calculation type you want.

A

Inputting Sample Data

Frequency On (FreqOn)

The following shows the key operations required when inputting class values (

x 1

,

y 1

), (

x 2

,

y 2

), ...(

xn

,

yn

), and frequencies Freq1, Freq2, ... Freq

n

.

{

x 1

}

,{

y 1

}

1,(;) {Freq1} m (DT)

{

x 2

}

,{

y 2

}

1,(;) {Freq2}

m (DT)

{

xn

}

,{

yn

}

1,(;) {Freq

n

}

m (DT)

Note

If the frequency of a class value is only one, you can input it by pressing {

xn

}

,{

yn

}

m (DT)

only (without specifying the frequency).

E-33

Frequency Off (FreqOff)

In this case, input each individual data item as shown below.

{

x 1

}

,{

y 1

}

m (DT)

{

x 2

}

,{

y 2

}

m (DT)

{

xn

}

,{

yn

}

m (DT)

A

Viewing Current Sample Data

After inputting sample data, you can press

c to scroll through the data in the sequence

you input it. The

$ symbol indicates there is data below the sample that is currently on the

display. The

` symbol indicates there is data above.

When the statistical frequency setting is FreqOn, data is displayed in the sequence:

x 1

,

y 1

,

Freq1,

x 2

,

y 2

, Freq2, and so on. In the case of FreqOff, it is displayed in the sequence:

x 1

,

y 1

,

x 2

,

y 2

,

x 3

,

y 3

, and so on. You can also use

f to scroll in the reverse direction.

A

Editing a Data Sample

To edit a data sample, recall it, input the new value(s), and then press

E.

A

Deleting a Data Sample

To delete a data sample, recall it and then press

1m(CL).

A

Deleting All Sample Data

See “Deleting All Sample Data” (page 31).

A Statistical Calculations Using Input Sample Data

To perform a statistical calculation, input the applicable command and then press E.

A

REG Mode Statistical Command Reference

Sum and Number of Sample Command (S-SUM Menu)

x2 11(S-SUM)1

Obtains the sum of squares of the sample

x-data.

Σx2 = Σxi2

x 11(S-SUM)2

Obtains the sum of the sample x-data.

Σx = Σxi

n 11(S-SUM)3

Obtains the number of samples.

y2 11(S-SUM)e1

Obtains the sum of squares of the sample

y-data.

Σy2 = Σyi2

y 11(S-SUM)e2

Obtains the sum of the sample y-data.

Σy = Σyi

xy 11(S-SUM)e3

Obtains the sum of products of the sample

x-data and y-data.

Σxy = Σxiyi

E-34

Mean and Standard Deviation Commands (VAR Menu)

¯x 12(S-VAR)1(VAR)1

Obtains the mean of the sample x-data.

oΣxi

n

=

σx 12(S-VAR)1(VAR)2

Obtains the population standard deviation

of the sample x-data.

σxn

=Σ(xi – o)2

x2y 11(S-SUM)d1

Obtains the sum of squares of the sample

x-data multiplied by the sample y-data.

Σx2y = Σxi2yi

x3 11(S-SUM)d2

Obtains the sum of cubes of the sample

x-data.

Σx3 = Σxi3

x4 11(S-SUM)d3

Obtains the sum of the fourth power of the

sample x-data.

Σx4 = Σxi4

sx 12(S-VAR)1(VAR)3

Obtains the sample standard deviation of

the sample x-data.

sxn – 1

=Σ(xi – o)2

¯y 12(S-VAR)1(VAR)e1

Obtains the mean of the sample y-data.

pΣyi

n

=

σy 12(S-VAR)1(VAR)e2

Obtains the population standard deviation

of the sample y-data.

σyn

=Σ (yi – y)2

sy

12(S-VAR)

1(VAR)

e3

Obtains the sample standard deviation of

the sample

y

-data.

syn – 1

=Σ (yi – y)2

Regression Coefficient and Estimated Value Commands for Non-

quadratic Regression (VAR Menu)

a

12(S-VAR)

1(VAR)

ee1

Obtains constant term a of the regression formula.

b

12(S-VAR)

1(VAR)

ee2

Obtains coefficient b of the regression formula.

E-35

r

12(S-VAR)

1(VAR)

ee3

Obtains correlation coefficient r

.

ˆ x

12(S-VAR)

1(VAR)

d1

Taking the value input immediately before this command as the

y

-value, obtains the

estimated value of

x

based on the regression formula for the currently selected regression

calculation .

ˆ y

12(S-VAR)

1(VAR)

d2

Taking the value input immediately before this command as the

x

-value, obtains the

estimated value of

y

based on the regression formula for the currently selected regression

calculation.

Regression Coefficient and Estimated Value Commands for Quadratic

Regression (VAR Menu)

a

12(S-VAR)

1(VAR)

ee1

Obtains constant term a of the regression formula.

b

12(S-VAR)

1(VAR)

ee2

Obtains coefficient b of the regression formula.

c

12(S-VAR)

1(VAR)

ee3

Obtains coefficient c of the regression formula.

ˆ x 1

12(S-VAR)

1(VAR)

d1

Taking the value input immediately before this command as the

y

-value, uses the formula

on page 37 to determine one estimated value of

x

.

ˆ x 2

12(S-VAR)

1(VAR)

d2

Taking the value input immediately before this command as the

y

-value, uses the formula

on page 37 to determine one more estimated value of

x

.

ˆ y

12(S-VAR)

1(VAR)

d3

Taking the value input immediately before this command as the

x

-value, uses the formula

on page 37 to determine the estimated value of

y

.

Minimum and Maximum Value Commands (MINMAX Menu)

minX

12(S-VAR)

2(MINMAX)

1

Obtains the minimum value of the sample

x

-data.

E-36

maxX

12(S-VAR)

2(MINMAX)

2

Obtains the maximum value of the sample

x

-data.

minY

12(S-VAR)

2(MINMAX)

e1

Obtains the minimum value of the sample

y

-data.

maxY

12(S-VAR)

2(MINMAX)

e2

Obtains the maximum value of the sample

y

-data.

A

Regression Coefficient and Estimated Value Calculation

Formula Table

Linear Regression

Command Calculation Formula

Regression Formula

Constant Term a a =n

Σyi – b.Σxi

Regression Coefficient b b =n.Σxi2 – (Σxi)2

n.Σxiyi – Σxi.Σyi

Correlation Coefficient

r r =

{n.Σxi2 – (Σxi)2}{n.Σyi2 – (Σyi)2}

n.Σxiyi – Σxi.Σyi

Estimated Value mmy – a

b

=

Estimated Value  n = a + bx

Quadratic Regression

Command Calculation Formula

Regression Formula

Constant Term a a = – b

(

)

– c

(

)

n

Σyi

n

Σxi

n

Σxi2

Regression Coefficient b b =Sxx.Sx2x2

– (Sxx2)2

Sxy.Sx2x2

– Sx2y.Sxx2

Regression Coefficient c c =Sxx.Sx2x2 – (Sxx2)2

Sx2y.Sxx – Sxy.Sxx2

However,

(Σxi)2

Sxx = Σxi2–n

Sxy = Σxiyi –n

(Σxi.Σyi)

Sxx2 = Σxi3

–n

(Σxi.Σxi2)

Sx2x2 = Σxi4

–n

(Σxi2)2

Sx2y = Σxi2yi –n

(Σxi2.Σyi)

E-37

Command Calculation Formula

Estimated Value m

1 m1 =2c

– b +b2 – 4c(a – y)

Estimated Value m

2 m2 =2c

– b –b2 – 4c(a – y)

Estimated Value nn = a + bx + cx2

Logarithmic Regression

Command Calculation Formula

Regression Formula

Constant Term a a =n

Σyi – b.Σlnxi

Regression Coefficient b b =n.Σ(lnxi)2 – (Σlnxi)2

n.Σ(lnxi)yi – Σlnxi.Σyi

Correlation Coefficient r r =

{n.Σ(lnxi)2 – (Σlnxi)2}{n.Σyi2 – (Σyi)2}

n.Σ(lnxi)yi – Σlnxi.Σyi

Estimated Value mm = e

y – a

b

Estimated Value nn = a + bln

x

e Exponential Regression

Command Calculation Formula

Regression Formula

Constant Term a a = exp

(

)

n

Σlnyi – b.Σxi

Regression Coefficient b b =n.Σxi2 – (Σxi)2

n.Σxilnyi – Σxi.Σlnyi

Correlation Coefficient

r r =

{n.Σxi2 – (Σxi)2}{n.Σ(lnyi)2 – (Σlnyi)2}

n.Σxilnyi – Σxi.Σlnyi

Estimated Value m

m

=b

lny – lna

Estimated Value nn = aebx

E-38

ab Exponential Regression

Command Calculation Formula

Regression Formula

Constant Term a a = exp

(

)

n

Σlnyi – lnb.Σxi

Regression Coefficient b b = exp

(

)

n.Σxi2 – (Σxi)2

n.Σxilnyi – Σxi.Σlnyi

Correlation Coefficient

r r =

{n.Σxi2 – (Σxi)2}{n.Σ(lnyi)2 – (Σlnyi)2}

n.Σxilnyi – Σxi.Σlnyi

Estimated Value mm =lnb

lny – lna

Estimated Value nn = ab

x

Power Regression

Command Calculation Formula

Regression Formula

Constant Term a a = exp

(

)

n

Σlnyi – b.Σlnxi

Regression Coefficient b b =n.Σ(lnxi)2 – (Σlnxi)2

n.Σlnxilnyi – Σlnxi.Σlnyi

Correlation Coefficient

r r =

{n.Σ(lnxi)2 – (Σlnxi)2}{n.Σ(lnyi)2 – (Σlnyi)2}

n.Σlnxilnyi – Σlnxi.Σlnyi

Estimated Value mm = eb

ln y – ln a

Estimated Value nn = axb

Inverse Regression

Command Calculation Formula

Regression Formula

Constant Term a a =n

Σyi – b.Σxi–1

Regression Coefficient b b =Sxx

Sxy

E-39

Command Calculation Formula

Correlation Coefficient

r r = Sxx.Syy

Sxy

However,

Command Calculation Formula

Estimated Value mm = y – a

b

Estimated Value nn = a + x

b

k Statistical Calculation Example

The nearby data shows how the weight of a newborn at various

numbers of days after birth.

1 Obtain the regression formula and correlation coefficient

produced by linear regression of the data.

2 Obtain the regression formula and correlation coefficient

produced by logarithmic regression of the data.

3 Predict the weight 350 days after birth based on the

regression formula that best fits the trend of the data in

accordance with the regression results.

Operation Procedure

Enter the REG Mode and select linear regression:

N5(REG)

1(Lin)

Select FreqOff for the statistical frequency setting:

1N(SETUP)

dd2(FreqOff)

Input the sample data:

20,3150m (DT)50,4800m (DT)

80,6420m (DT)110,7310m (DT)

140,7940m (DT)170,8690m (DT)

200,8800m (DT)230,9130m (DT)

260,9270m (DT)290,9310m (DT)

320,9390m (DT)

1 Linear Regression

Regression Formula Contant Term a:

12(S-VAR)1(VAR)ee1(a)E

Sxx = Σ(xi–1)2 –

n

(Σxi–1)2

Syy = Σyi2–n

(Σyi)2

Sxy = Σ(xi–1)yi – n

Σxi–1.Σyi

Number

of Days

Weight

(g)

20 3150

50 4800

80 6420

110 7310

140 7940

170 8690

200 8800

230 9130

260 9270

290 9310

320 9390

4446575758

E-40

Regression Coefficient b:

12(S-VAR)1(VAR)ee2(b)E

Correlation Coefficient:

12(S-VAR)1(VAR)ee3(r)E

2 Logarithmic Regression

Select logarithmic regression:

12(S-VAR)3(TYPE)2(Log)

Regression Formula Contant Term a:

A12(S-VAR)1(VAR)ee1(a)E

Regression Coefficient b:

12(S-VAR)1(VAR)ee2(b)E

Correlation Coefficient:

12(S-VAR)1(VAR)ee3(r)E

3 Weight Prediction

The absolute value of the correlation coefficient for logarithmic regression is closer to 1, so

perform the weight prediction calculation using logarithmic regression.

Obtain  when x = 350:

350

12(S-VAR)1(VAR)d2(n)E

Base-n Calculations (BASE)

To perform the example operations in this section, first select BASE as the calculation

mode.

k Performing Base-n Calculations

A Specifying the Default Number Base

Use the following keys to select a default number base x(DEC) for decimal, M(HEX) for

hexadecimal, l(BIN) for binary, or i(OCT) for octal.

1887575758

0904793561

20

x

1

=

–

4209356544

2425756228

0991493123

350

y

1000056129

E-41

A Example Base-n Calculations

Example: To select binary as the number base and calculate 12 + 12

Al(BIN)1+1E

• Inputting an invalid value causes a Syntax ERROR.

• In the BASE Mode, input of fractional (decimal) values and exponential values is not

supported. Anything to the right of the decimal point of calculation results is cut off.

A Hexadecimal Value Input and Calculation Example

Use the following keys to input the letters required for hexadecimal values: -(A), $(B),

w(C), s(D), c(E), t(F).

Example: To select hexadecimal as the number base and calculate 1F16 + 116

AM(HEX)1t(F)+1E

A Effective Calculation Ranges

Number Base Effective Range

Binary Positive: 0 < x < 111111111

Negative: 1000000000 < x < 1111111111

Octal Positive: 0 < x < 3777777777

Negative: 4000000000 < x < 7777777777

Decimal –2147483648 < x < 2147483647

Hexadecimal Positive: 0 < x < 7FFFFFFF

Negative: 80000000 < x < FFFFFFFF

A Math ERROR occurs when a calculation result is outside of the applicable range for the

current default number base.

k Converting a Displayed Result to another Number Base

Pressing

x(DEC),

M(HEX),

l(BIN), or

i(OCT) while a calculation result is displayed

will convert the result to the corresponding number base.

Example: To convert the decimal value 30

10

to binary, octal, and hexadecimal format

Ax(DEC)30E

l(BIN)

i(OCT)

20

H

30

d

11110

b

36

o

1+1

10

b

Number base indicator

(d: decimal, H: hexadecimal, b: binary, o: octal)

E-42

M(HEX)

k Using the LOGIC Menu

In the BASE Mode, the

X key changes function to become a LOGIC menu display key.

The LOGIC menu has three screens, and you can use

d and

e to navigate between

them.

k Specifying a Number Base for a Particular Value

You can specify a number base that is different from the current default number base while

inputting a value.

A

Example Calculation Using Base-

n

Specification

Example: To perform the calculation 5

10

+ 5

16

, and display the result in binary

Al(BIN)

X(LOGIC)

d1(d)

5+X(LOGIC)

d2(h)

5E

k Performing Calculations Using Logical Operations and

Negative Binary Values

Your calculator can perform 10-digit (10-bit) binary logical operations and negative value

calculations. All of the examples shown below are performed with BIN (binary) set as the

default number base.

A

Logical Product (and)

Returns the result of a bitwise product.

Example: 1010

2

and 1100

2

= 1000

2

1010X(LOGIC)1(and)1100E

A

Logical Sum (or)

Returns the result of a bitwise sum.

Example: 1011

2

or 11010

2

= 11011

2

1011X(LOGIC)2(or)11010E

A

Exclusive Logical Sum (xor)

Returns the result of a bitwise exclusive logical sum.

Example: 1010

2

xor 1100

2

= 110

2

1010X(LOGIC)e1(xor)1100E

1E

H

d5+h5

1010

b

1000

b

11011

b

110

b

E-43

A

Exclusive Logical Sum Negation (xnor)

Returns the result of the negation of a bitwise exclusive logical sum.

Example: 1111

2

xnor 101

2

= 1111110101

2

1111X(LOGIC)3(xnor)101E

A

Complement/Inversion (Not)

Returns the complement (bitwise inversion) of a value.

Example: Not(1010

2

) = 1111110101

2

X(LOGIC)e2(Not)1010)E

A

Negation (Neg)

Returns the two’s complement of a value.

Example: Neg(101101

2

) = 1111010011

2

X(LOGIC)e3(Neg)101101)E

Program Mode (PRGM)

You can use the PRGM Mode to create and store programs for calculations you need to

perform on a regular basis. You can include any calculation that can be performed in the

COMP, CMPLX, BASE, SD, or REG Mode in a program.

k Program Mode Overview

A Specifying a Program Run Mode

Though you create and run programs in the PRGM Mode, each program has a “run mode”

that it runs in. You can specify COMP, CMPLX, BASE, SD, or REG as a program’s run

mode. This means you need to think about what you want your program to do and select

the appropriate run mode.

A Program Memory

Program memory has a total capacity of 390 bytes, which can be shared by up to four

programs. Further program storage is not possible after program memory becomes full.

k Creating a Program

A

Creating a New Program

Example: To create a program that converts inches to centimeters (1 inch = 2.54 cm)

? → A : A × 2.54

1111110101

b

1111110101

b

1111010011

b

E-44

1. Press

,g(PRGM) to enter the PRGM Mode.

2. Press

b(EDIT).

Program areas that already contain program data (P1 through P4)

Remaining program memory capacity

3. Press the number key that corresponds to an unused program area number.

• This displays the run mode selection menu. Use e and d to switch between menu

screen 1 and screen 2.

MODE

:

BASE SD REG

345

MODE

:

COMP CMPLX

12

Screen 1 Screen 2

4. Press the number key that corresponds to the mode you want to assign as the program’s

run mode.

• Here, select b(COMP) on screen 1. This selects COMP

as the run mode, and displays the program editing

screen.

Important!

You cannot change the run mode of a program once it has been assigned. A run mode can

be assigned only when you are creating a new program.

5. Input the program.

• Here we will input the program shown below.

Program ? → A : A × 2.54

Key Operation

!

d (P-CMD)b (?)

!~ (→ )- (A)w

a- (A)*c.fe

• !d(P-CMD) displays a special program command input screen. See “Inputting

Commands” on page 46 for more information.

6. After inputting the program, press A or !5(EXIT).

• To run the program you just created, press w here to display the RUN Program

screen. For more information, see “Running a Program” below.

• To return to the normal calculation screen, press ,b to enter the COMP Mode.

ED I T RUN DEL

123

EDIT Pro

g

ram

P-1234 380

I

000

?

→

A:A×2.54

010

E-45

A

Editing an Existing Program

1. Press

,g(PRGM)b(EDIT) to display the EDIT Program screen.

2. Use number keys b through e to select the program area that contains the program

you want to edit.

3. Use

e and d to move the cursor around the program, and perform the required

operations to edit the contents of the program or to add new contents.

• Pressing f jumps to the beginning of the program, while c jumps to the end.

4. After you finish editing the program, press A or !5(EXIT).

k Running a Program

You can run a program in the PRGM Mode or from another mode.

A Running a Program from Outside the PRGM Mode

1. Press

5.

2. Use number keys b through e to select a program area and execute its program.

A Running a Program in the PRGM Mode

1. Press

,g(PRGM) to display the PRGM Mode initial screen.

2. Press

c(RUN).

• This will display the RUN Program screen.

Program areas that already contain program data (P1 through P4)

Remaining program memory capacity

3. Use number keys b through e to select the program area that contains the program

you want to run.

• This will execute the program in the program area you select.

A What to do if an error message appears

Press d or e. This will display the editing screen for the program, with the cursor located

at the location where the error was generated so you can correct the problem.

k Deleting a Program

You can delete an existing program by specifying its program area number.

A

Deleting the Program in a Specific Program Area

1. Press

,g(PRGM) to display the PRGM Mode initial screen.

2. Press

d(DEL).

Program areas that already contain program data (P1 through P4)

Remaining program memory capacity

RUN P r o

g

ram

P-1234 380

DELETE Pr o

g

ram

P-1234 380

E-46

3. Use number keys b through e to select the program area whose program you want

to delete.

• The symbol next to the number of the program area

that contained the program you just deleted will turn off,

and the remaining program memory capacity value will

increase.

k Inputting Commands

A

Inputting Special Program Commands

1. While the program editing screen is on the display, press

!d (P-CMD).

• This displays page 1 of the command menu.

2. Use

e and d to scroll through the pages and display the one that contains the

command you want.

3. Use number keys

b through

e to select and input the command you want.

Note

To input a separator symbol (:), press

w.

A

Functions that Can be Input as Program Commands

You can input the settings and other operations that you perform during normal calculations

as program commands. For more information, see the “Command Reference” below.

k Command Reference

This section provides details on each of the commands that you can use in programs.

Commands that have

g in the title can be input on the screen that appears when you

press

!d(P-CMD) or

5.

A

Basic Operation Commands

g

? (Input Prompt)

Syntax ?

→ {variable}

Function Displays the input prompt “{variable}?” and assigns the input value to a

variable.

Example ?

→ A

→ (Variable Assignment)

Syntax {expression ; ?}

→ {variable}

Function Assigns the value obtained by the element on the left to the variable on the

right.

Example A+5

→ A

: (Separator Code)

Syntax {statement} : {statement} : ... : {statement}

Function Separates statements. Does not stop program execution.

Example ?

→

A : A

2

: Ans

2

DELETE Pr o

g

ram

P-1234 390

E-47

^ (Output Command)

Syntax {statement}

^ {statement}

Function Pauses program execution and displays the result of the current execution.

The

Q

symbol is turned on while program execution is paused by this

command.

Example ?

→

A : A

2

^ Ans

2

A

Unconditional Jump Command

g

Goto ~ Lbl

Syntax Goto

n

: .... : Lbl

n

or Lbl

n

: .... : Goto

n

(

n

= integer from 0 to 9)

Function Execution of Goto

n

jumps to corresponding Lbl

n

.

Example ?

→

A : Lbl 1 : ?

→

B : A × B ÷ 2

^ Goto 1

Important!

A Syntax ERROR occurs if there is no corresponding Lbl

n

in the same program where

Goto

n

is located.

A

Conditional Jump Commands and Conditional Expressions

g

S

Syntax

1 {expression} {relational operator} {expression}

S {statement1} :

{statement2} : ....

2 {expression}

S {statement1} : {statement2} : ....

Function Conditional branching command used in combination with relational

operators (=, ≠, >,

>, <,

<).

Syntax

1: {statement1} is executed if the condition to the left of the

S

command is true, and then {statement2} and everything after it is executed

in sequence. {statement1} is skipped if the condition to the left of the

S

command is false, and then {statement2} and everything after it is executed.

Syntax

2: A non-zero evaluation result of the condition to the left of the

S

command is interpreted as “true”, so {statement1} is executed, followed by

{statement2} and everything after it in succession. A zero evaluation result

of the condition to the left of the

S command is interpreted as “false”, so

{statement1} is skipped, and {statement2} and everything after it is executed.

Example Lbl 1 : ?

→

A : A

> 0

S

'(A)

^ Goto 1

=, ≠, >, > , <, < (Relational Operators)

Syntax {expression} {relational operator} {expression}

Function These commands evaluate the expressions on either side, and return a value

of true (1) or false (0). These commands are used in combination with the

branching command

S, and when structuring the {conditional expression} of

If statements and While statements.

Example See the entries for

S (page 47), If statement (page 48), and While statement

(page 49).

E-48

Note

These commands evaluate the expressions on either side, and return 1 if true and 0 if false,

and store the result in Ans.

A

Control Structure Commands/If Statement

g

The If statement is used to control program execution branching according to whether the

expression following If (which is the branching condition) is true or false.

If Statement Precautions

• An If must always be accompanied by a Then. Using an If without a corresponding Then

will result in a Syntax ERROR.

• An expression, Goto command, or Break command can be used for the {expression*}

following Then and Else.

If~Then (~Else) ~IfEnd

Syntax If {conditional expression} : Then {expression*} : Else {expression*} : IfEnd :

{statement} : ...

Function • The statements following Then are executed up to Else, and then the

statements following IfEnd are executed when the conditional statement

following If is true. The statements following Else and then the statements

following IfEnd are executed when the conditional statement following If is

false.

• Else {expression} may be omitted.

• Always include the IfEnd:{statement}. Omitting it will not cause an error,

but certain program contents can cause unexpected execution results by

everything after the If statement.

Example 1 ?

→

A : If A < 10 : Then 10A

^ Else 9A

^ IfEnd : Ans×1.05

Example 2 ?

→

A : If A > 0 : Then A × 10

→

A : IfEnd : Ans×1.05

A

Control Structure Commands/For Statement

g

The For statement repeats execution of the statements between For and Next as long as

the value assigned to the control variable is within the specified range.

For Statement Precautions

A For statement must always be accompanied by a Next statement. Using a For without a

corresponding Next will result in a Syntax ERROR.

For~To~Next

Syntax For {expression (starting value)}

→

{variable (control variable)} To {expression

(ending value)} : {statement} : ... {statement} : Next : ....

Function Execution of the statements from For to Next repeats as the control variable

is incremented by 1 with each execution, starting from the starting value.

When the value of the control value reaches the ending value, execution

jumps to the statement following Next. Program execution stops if there is

no statement following Next.

Example For 1

→ A To 10 : A

2

→ B : B

^ Next

E-49

For~To~Step~Next

Syntax For {expression (starting value)}

→

{variable (control variable)} To {expression

(ending value)} Step {expression (step)} : {statement} : ... {statement} :

Next : ....

Function Execution of the statements from For to Next repeats as the control variable

is incremented by the step amount with each execution, starting from the

starting value. Except for that, this command is the same as For~To~Next.

Example For 1

→ A To 10 Step 0.5 : A

2

→ B : B

^ Next

A

Control Structure Commands/While Statement

g

While~WhileEnd

Syntax While {conditional expression} : {statement} : ... {statement} : WhileEnd : ....

Function The statements from While to WhileEnd are repeated while the conditional

expression following While is true (non-zero). When the conditional

expression following While becomes false (0), the statement following

WhileEnd is executed.

Example ?

→ A : While A < 10 : A

2

^ A+1

→ A : WhileEnd : A÷2

Note

If the condition of the While statement is false the first time this command is executed,

execution jumps directly to the statement following WhileEnd without executing the

statements from While to WhileEnd even once.

A

Program Control Commands

g

Break

Syntax .. : {Then ; Else ;

S } Break : ..

Function This command forces a break in a For or While loop, and jumps to the next

command. Normally, this command is used inside of a Then statement in

order to apply a Break condition.

Example ?

→ A : While A > 0 : If A > 2 : Then Break : IfEnd : WhileEnd : A

^

A

Setup Commands

These commands function the same way as the calculator’s various setup settings. For

more information, see “Calculator Setup” on page 6.

Important!

With some setup commands, the settings you configure remain in effect even after you

finish running the program.

E-50

Angle Unit Commands

Deg, Rad, Gra (COMP, CMPLX, SD, REG)

Syntax .. : Deg : ..

.. : Rad : ..

.. : Gra : ..

Operation

!,(SETUP)b(Deg)

!,(SETUP)c(Rad)

!,(SETUP)d(Gra)

Function These commands specify the angle unit setting.

Display Format Command

Fix (COMP, CMPLX, SD, REG)

Syntax .. : Fix {

n

} : .. (

n

= an integer from 0 to 9)

Operation

!,(SETUP)

eb(Fix)

a to j

Function This command fixes the number of decimal places (from 0 to 9) for output of

calculation results.

Sci (COMP, CMPLX, SD, REG)

Syntax .. : Sci {

n

} : .. (

n

= an integer from 0 to 9)

Operation

!,(SETUP)ec(Sci)

a to

j

Function This command fixes the number of significant digits (from 1 to 10) for output

of calculation results.

Pressing

!,(SETUP)ec(Sci) and then

a specifies 10 significant

digits.

Norm (COMP, CMPLX, SD, REG)

Syntax .. : Norm {1 ; 2} : ..

Operation

!,(SETUP)ed(Norm)

b or

c

Function This command specifies either Norm1 or Norm2 for output of calculation

results.

Statistical Frequency Command

FreqOn, FreqOff (SD, REG)

Syntax .. : FreqOn : ..

.. : FreqOff : ..

Operation

!,(SETUP)db(FreqOn)

!,(SETUP)dc(FreqOff)

Function This command turns statistical frequency on (FreqOn) or off (FreqOff).

E-51

A

Clear Commands

ClrMemory (COMP, CMPLX, BASE)

Syntax .. : ClrMemory : ..

Operation

!j(CLR)

b(Mem)

Function This command clears all variables to zero.

Note

To clear a specific variable, use 0

→

{variable}.

ClrStat (SD, REG)

Syntax .. : ClrStat : ..

Operation

!j(CLR)

b(Stat)

Function This command clears all statistical sample data currently in memory.

A

Independent Memory Commands

M+, M– (COMP, CMPLX, BASE)

Syntax .. : {expression} M+ : .. / .. : {expression} M– : ..

Operation

l/

!l(M–)

Function M+ adds the value of the expression to independent memory, while M–

subtracts it.

A

Rounding (Rnd) Command

Rnd( (COMP, CMPLX, SD, REG)

Syntax .. : {expression} : Rnd(Ans : ..

Operation

!a(Rnd)

Function This command rounds a calculation result in accordance with the number of

digits specified by the display format.

A Number Base Commands

Dec, Hex, Bin, Oct (BASE)

Syntax .. : Dec : .. / .. : Hex : .. / .. : Bin : .. / .. : Oct : ..

Operation x(DEC)/M(HEX)/l(BIN)/I(OCT)

Function These commands specify the number base for base-n calculations.

E-52

A Statistical Data Input Command

DT (SD, REG)

Syntax .. : {expression (x-value)} ; {expression (Freq-value)} DT : ..

..................SD Mode, FreqOn

.. : {expression (x-value)} DT : .. ..................SD Mode, FreqOff

.. : {expression (x-value)} , {expression (y-value)} ; {expression (Freq-value)}

DT : .. ............... REG Mode, FreqOn

.. : {expression (x-value)} , {expression (y-value)} DT : ..

............... REG Mode, FreqOff

Important!

To input a semicolon (;) in the above syntax, press

!,(;). To input a comma (,), press

,.

Operation

l(Inputs DT.)

Function Use this command to input one set of sample data. The DT command

functions the same way as the

l key ( DT key) in the SD Mode and REG

Mode.

A

Functions Not Supported in Programs

The following functions are not supported inside of functions.

• Calculation result conversion functions (ENG

/

, ENG

,

, Sexagesimal

↔

Decimal

Conversion, Fraction

↔

Decimal Conversion)

• Display switching (

!w(Re

⇔

Im)) while a complex number calculation result is

displayed

• Reset (

!j(CLR)

d(All)

w)

• Setup information clear (

!j(CLR)

c(Setup)

w)

E-53

Appendix

k Calculation Priority Sequence

The calculator performs calculations you input in accordance with the priority sequence shown

below.

• Basically, calculations are performed from left to right.

• Calculations enclosed in parentheses are given priority.

Sequence Operation Type Description

1 Parenthetical Functions Pol(, Rec(, ∫(, d/dx(, sin(, cos(, tan(, sin –1 (, cos –1 (,

tan –1 (, sinh(, cosh(, tanh(, sinh –1 (, cosh –1 (,

tanh –1 (, log(, ln(, e ^(, 10^(, ' (, 3

' (, arg(, Abs(,

Conjg(, Not(, Neg(, Rnd(

2 Functions Preceded by Values

Power, Power Root

Percent

x

2 , x

3 , x

–1 , x !, ° ´ ˝, °, r , g

^(, x

' (

%

3 Fractions a b

/

c

4 Prefix Symbols (–) (minus sign)

d, h, b, o (number base symbol)

5 Statistical Estimated Value

Calculations

m , n , m

1 , m

2

6 Omitted Multiplication Sign Multiplication sign can be omitted immediately

before π , e , variables (2 π , 5A, π A, 2

i , etc.),

parenthetical functions (2' (3), Asin(30), etc.)

and prefix symbols (except for the minus sign).

7 Permutation, Combination

Complex Number Symbol

n P

r , n C r

∠

8 Multiplication, Division ×, ÷

9 Addition, Subtraction +, −

10 Relational Operators =, ≠, >, <, > , <

11 Logical Product and

12 Logical Sum, Exclusive Logical

Sum, Exclusive Negative

Logical Sum

or, xor, xnor

Note

• If a calculation contains a negative value, you may need to enclose the negative value in

parentheses. If you want to square the value –2, for example, you need to input: (–2)

2

. This is

because

x 2

is a function preceded by a value (Priority 2, above), whose priority is greater than

the negative sign, which is a prefix symbol (Priority 4).

-cxw –22 = –4 (-c)xw (–2)2 = 4

E-54

• As shown in the examples below, multiplication where the sign is omitted is given higher priority

than signed multiplication and division.

1 ÷ 2π = 1

2π = 0.159154943

1 ÷ 2 × π = 1

2π = 1.570796327

k Calculation Ranges, Number of Digits, and Precision

The following table shows the general calculation range (value input and output range), number of

digits used for internal calculations, and calculation precision.

Calculation Range ±1×10 –99 to ±9.999999999×10 99 or 0

Internal Calculation 15 digits

Precision

In general, ±1 at the 10th digit for a single calculation. Error in the

case of a calculation result in exponential format is ±1 at the least

signifi cant digits of the mantissa. Errors are cumulative in the case of

consecutive calculations.

A

Function Calculation Input Ranges and Precision

Functions Input Range

sinx

cosx

DEG 0 < | x | < 9×109

RAD 0 < | x | < 157079632.7

GRA 0 < | x | < 1×1010

tanx

DEG Same as sinx, except when | x | = (2n–1)×90.

RAD Same as sinx, except when | x | = (2n–1)×π/2.

GRA Same as sinx, except when | x | = (2n–1)×100.

sin–1x0 < | x | < 1

cos–1x

tan–1x0 < | x | < 9.999999999×1099

sinhx0 < | x | < 230.2585092

coshx

sinh–1x0 < | x | < 4.999999999×1099

cosh–1x1 < x < 4.999999999×1099

tanhx0 < | x | < 9.999999999×1099

tanh–1x0 < | x | < 9.999999999×10–1

logx/lnx0 < x < 9.999999999×1099

10x–9.999999999×1099 < x < 99.99999999

ex–9.999999999×1099 < x < 230.2585092

E-55

Functions Input Range

'

x0 < x < 1×10100

x2| x | < 1×1050

1/x| x | < 1×10100 ; x G 0

3'

x| x | < 1×10100

x!0

< x < 69 (x is an integer)

nPr0 < n < 1×1010, 0 < r < n (n, r are integers)

1 < {n!/(n–r)!} < 1×10100

nCr0 < n < 1×1010, 0 < r < n (n, r are integers)

1 < n!/r! < 1×10100 or 1 < n!/(n–r)! < 1×10100

Pol(x, y)| x |, | y | < 9.999999999×1099

x2+y2 < 9.999999999×1099

Rec(r,

θ

)0 < r < 9.999999999×1099

θ

: Same as sinx

°’ ” | a |, b, c < 1×10100

0 < b, c

| x | < 1×10100

Decimal ↔ Sexagesimal Conversions

0°0´0˝ < | x | < 9999999°59´59˝

^(xy)

x > 0: –1×10100 < ylog x < 100

x = 0: y > 0

x < 0: y = n, m

2n+1 (m, n are integers)

However: –1×10100 < ylog | x | < 100

x'

y

y > 0: x G 0, –1×10100 < 1/xlogy < 100

y = 0: x > 0

y < 0: x = 2n+1, 2n+1

m (m G 0; m, n are integers)

However: –1×10100 < 1/xlog | y | < 100

a b/cTotal of integer, numerator, and denominator must be 10 digits or less (including

separtor symbols).

• ^(

x y

),

x '

y

,

3

',

x

!,

n

P

r

,

n

C

r

type functions require consecutive internal calculation, which can

result in accumulation of errors that occur within each individual calculation.

• Errors are cumulative and tend to be large in the vicinity of a function’s singular point and

inflection point.

k Error Messages

An error message will appear on the screen if you perform a

calculation that causes a calculator’s limit to be exceeded, or if you

try to perform some operation that is not allowed.

Mat h ERROR

Sample Error Message

E-56

A

Recovering from an Error Message

You can recover from an error message by performing the key operations described below,

regardless of the error type.

• Press

d or

e to display the editing screen for the calculation expression you input immediately

before the error occurred, with the cursor positioned at the location that caused the error. For

more information, see “Finding the Location of an Error” on page 10.

• Pressing

A will clear the calculation expression you input immediately before the error occurred.

Note that a calculation expression that causes an error will not be included in calculation history.

A

Error Message Reference

This section lists all of the error messages that the calculator displays, as well as their causes and

what you need to do to avoid them.

Math ERROR

Cause • An intermediate or the final result of the calculation falls outside of the

allowable calculation range.

• An input value is outside the allowable input range.

• You are trying to perform an illegal mathematical operation (such as

division by zero).

Action • Check your input values and reduce the number of digits, if required.

• When using independent memory or a variable as the argument of a

function, make sure that the memory or variable value is within the

allowable range for the function.

For information about the allowable value input range, see “Calculation Ranges, Number of Digits,

and Precision” on page 54.

Stack ERROR

Cause The calculation has causes the capacity of the numeric stack or the

command stack to be exceeded.

Action • Simplify the calculation expression so it does not exceed the capacity of

the stacks.

• Try splitting the calculation into two or more parts.

Syntax ERROR

Cause The calculation has a format problem.

Action Check the syntax and make the required corrections.

Argument ERROR

Cause The calculation has a problem with how an argument being used.

Action Check how arguments are being used and make the required corrections.

E-57

Time Out Error

Cause The current differential or integration calculation ends without the ending

condition being fulfi lled.

Action Differential or integration calculation: Try increasing the tol value. Note that

this also decreases solution precision.

Data Full

Cause You are attempting to store sample data in the SD Mode or REG Mode

when the allowable number of data samples are already stored in memory.

Action Keep the number of data samples within the allowable limit. For more

information, see “Maximum Number of Input Data Items” on page 29.

Go ERROR

Cause A program (that you created in the PRGM Mode) has a “Goto n ” command

without a corresponding “Lbl n ” label.

Action Either add a “Lbl n ” for the “Goto n ” command, or delete the applicable “Goto

n ” command.

k Before assuming malfunction of the calculator...

Perform the following steps whenever an error occurs during a calculation or when calculation

results are not what you expected. If one step does not correct the problem, move on to the next

step. Note that you should make copies of important copies of important data before performing

these steps.

1 Check the calculation expression to make sure it does not include any errors.

2 Make sure that you are using the correct mode for the type of calculation you are trying to

perform.

3 If the above steps do not restore normal operation, press the

p key. The calculator will perform

a self-check of its status as it starts up. If the calculator discovers a problem, it will return its

calculation mode and setup to their initial defaults, and clear all data currently in memory.

4 If step

3 does not restore normal operation, initialize all modes and settings by pressing

!j(CLR)

c(Setup)

w.

Power Requirements

A Replacing the Battery

Dim figures on the display of the calculator indicate that battery power is low. Continued

use of the calculator when the battery is low can result in improper operation. Replace the

battery as soon as possible when display figures become dim. Even if the calculator is

operating normally, replace the battery at least once every three years.

Important!

Removing the battery will cause all of the calculator’s memory contents to be deleted.

E-58

1. Press

1A(OFF) to turn off the calculator.

• To ensure that you do not accidentally turn on power while replacing the battery, slide

the hard case onto the front of the calculator.

2. Remove the cover as shown in the illustration and replace the

battery, taking care that its plus (+) and minus (–) ends are facing

correctly.

3. Replace the cover.

4. Initialize the calculator: O19(CLR)3(All)w(Yes)

• Do not skip the above step!

Screw

A

Auto Power Off

Your calculator will turn off automatically if you do not perform any operation for about 10

minutes. If this happens, press the

p key to turn the calculator back on.

Specifications

Power Requirements:

Solar Cell: Built into front of calculator (fixed)

Button Battery: LR44 (GPA76) × 1

Approximate Battery Life:

3 years (based on 1 hour of operation per day)

Operating Temperature: 0˚C to 40˚C (32˚F to 104˚F)

Dimensions: 11.1 (H) × 80 (W) × 162 (D) mm

3/8" (H) × 31/8" (W) × 63/8" (D)

Approximate Weight: 95 g (3.4 oz) including the battery

Bundled Accessories: Hard Case

Manufacturer:

CASIO COMPUTER CO., LTD.

6-2, Hon-machi 1-chome

Shibuya-ku, Tokyo 151-8543, Japan

Responsible within the European Union:

CASIO EUROPE GmbH

Casio-Platz 1

22848 Norderstedt, Germany

This mark applies in EU countries only.

CASIO COMPUTER CO., LTD.

6-2, Hon-machi 1-chome

Shibuya-ku, Tokyo 151-8543, Japan

SA1303-A Printed in China

© 2013 CASIO COMPUTER CO., LTD.