ENGLISH
ALPHA : Appears when K (STAT VAR), O or R is pressed.
FIX/SCI/ENG: Indicates the notation used to display a value.
DEG/RAD/GRAD: Indicates angular units.
(2sin30, etc.) I
n
C
r
,
n
P
r
O ×, ÷ P +, – { AND } OR, XOR, XNOR
q =, M+, M–, ⇒M, |DEG, |RAD, |GRAD, DATA, CD, →rθ, →xy
and other calculation ending instructions
•
If parentheses are used, parenthesized calculations have prec-
edence over any other calculations.
: Appears when matrix mode is selected.
: Appears when list mode is selected.
: Appears when statistics mode is selected.
SCIENTIFIC CALCULATOR
EL-506W
EL-546W
INITIAL SET UP
MODEL
M
?
: Indicates that a value is stored in the independent memory.
Mode Selection
:
Indicates that the calculator is waiting for a numerical
value to be entered, such as during simulation calculation.
OPERATION MANUAL
m0: Normal mode (NORMAL)
m1: Statistic mode (STAT)
m2: Equation mode (EQN)
m3: Complex number mode (CPLX)
m4: Matrix mode (MAT)
PRINTED IN CHINA / IMPRIMÉ EN CHINE / IMPRESO EN CHINA
04HGK (TINSE0719EH01)
: Appears when the calculator shows an angle as the result
in the complex calculation mode.
i
: Indicates an imaginary number is being displayed in the
complex calculation mode.
INTRODUCTION
m5: List mode (LIST)
SET UP menu
BEFORE USING THE CALCULATOR
Thank you for purchasing the SHARP Scientific Calculator Model
EL-506W/546W.
Key Notation Used in this Manual
In this manual, key operations are described as follows:
Press ” to display the SET UP menu.
About the calculation examples (including some formulas and
tables), refer to the reverse side of this English manual. Refer to
the number on the right of each title in the manual for use.
After reading this manual, store it in a convenient location for
future reference.
Note: Some of the models described in this manual may not be
available in some countries.
TAB
D0RG F1SE
•
A menu item can be selected by:
• moving the flashing cursor by using
To specify ex
To specify ln :
:
@e
I
><, then pressing ® (= key), or
To specify F : Kü
• pressing the number key corresponding to the menu item number.
If or
view the previous/next menu screen.
Functions that are printed in orange above the key require @ to
be pressed first before the key. When you specify the memory,
press K first. Numbers for input value are not shown as keys,
but as ordinary numbers.
•
•
is displayed on the screen, press [ or ] to
Press ª to exit the SET UP menu.
Operational Notes
[Determination of the Angular Unit]
The following three angular units (degrees, radians, and grads) can
be specified.
•
•
•
Do not carry the calculator around in your back pocket, as it
may break when you sit down. The display is made of glass
and is particularly fragile.
Keep the calculator away from extreme heat such as on a car
dashboard or near a heater, and avoid exposing it to exces-
sively humid or dusty environments.
Since this product is not waterproof, do not use it or store it
where fluids, for example water, can splash onto it. Raindrops,
water spray, juice, coffee, steam, perspiration, etc. will also
cause malfunction.
Clean with a soft, dry cloth. Do not use solvents or a wet cloth.
Do not drop it or apply excessive force.
Power On and Off
Press ª to turn the calculator on, and @F to turn it off.
•
•
•
DEG (°) : Press ”00.
RAD (rad): Press ”01.
GRAD (g) : Press ”02.
Clearing the Entry and Memories
Operation
Entry
M
A-F, X,Y
ANS STAT VAR*2
STAT*1
matA-D*3
L1-4*4
[Selecting the Display Notation and Decimal Places]
Four display notation systems are used to display calculation re-
sults: Floating point; Fixed decimal point; Scientific notation; and
Engineering notation.
(Display) F1-F4
ª
×
×
×
×
×
×
@c
•
When the FIX, SCI, or ENG symbol is displayed, the number of decimal
places (TAB) can be set to any value between 0 and 9. Displayed
values will be reduced to the corresponding number of digits.
Mode selection
@∏00*5
@∏10*6
•
•
•
•
•
Never dispose of batteries in a fire.
Keep batteries out of the reach of children.
This product, including accessories, may change due to up-
grading without prior notice.
[Setting the Floating Point Numbers System in Scientific Notation]
Two settings are used to display a floating point number: NORM1
(default setting) and NORM2. A number is automatically displayed
in scientific notation outside a preset range:
RESET switch
: Clear
× : Retain
1
*
*
*
*
*
*
Statistical data (entered data).
x¯, sx, σx, n, Σx, Σx2, ¯y, sy, σy, Σy, Σy2, Σxy, r, a, b, c.
Matrix memories (matA, matB, matC and matD)
List memories (L1, L2, L3 and L4)
2
3
4
5
6
NOTICE
•
•
NORM1: 0.000000001 ≤ x ≤ 9999999999
NORM2: 0.01 ≤ x ≤ 9999999999
•
•
SHARP strongly recommends that separate permanent
written records be kept of all important data. Data may be
lost or altered in virtually any electronic memory product
under certain circumstances. Therefore, SHARP assumes
no responsibility for data lost or otherwise rendered unusable
whether as a result of improper use, repairs, defects, battery
replacement, use after the specified battery life has expired,
or any other cause.
All variables are cleared.
This key combination functions the same as the RESET switch.
SCIENTIFIC CALCULATIONS
•
•
Press m0 to select the normal mode.
[Memory clear key]
MEM RESET
In each example, press ª to clear the display. If the FIX, SCI,
or ENG indicator is displayed, clear the indicator by selecting
‘NORM1’ from the SET UP menu.
Press @∏ to display the menu.
F1-F4, STAT VAR, matA-D, L1-4), press 00 0 or 0
1
•
To clear all variables (M, A-F, X, Y, ANS,
SHARP will not be liable nor responsible for any incidental or
consequential economic or property damage caused by
misuse and/or malfunctions of this product and its peripherals,
unless such liability is acknowledged by law.
®.
Arithmetic Operations
•
To RESET the calculator, press 10 or 1®.
The RESET operation will erase all data stored in memory, and
restore the calculator’s default setting.
•
The closing parenthesis ) just before = or ; may be
omitted.
Constant Calculations
♦ Press the RESET switch (on the back), with the tip of a ball-
point pen or similar object, only in the following cases. Do not
use an object with a breakable or sharp tip. Note that pressing
the RESET switch erases all data stored in memory.
Entering and Correcting the Equation
[Cursor keys]
•
In constant calculations, the addend becomes a constant. Sub-
traction and division are performed in the same manner. For
multiplication, the multiplicand becomes a constant.
•
Press < or > to move the cursor. You can also return to
the equation after getting an answer by pressing > (<).
See the next section for using the [ and ] keys.
See ‘SET UP menu’ for cursor use in the SET UP menu.
•
•
•
•
When using for the first time
After replacing the batteries
To clear all memory contents
When an abnormal condition occurs and all keys are inoperative.
•
In the constants calculations, constants will be displayed as K.
Functions
•
•
•
Refer to the calculation examples of each function.
Before starting calculations, specify the angular unit.
[Insert mode and Overwrite mode in the Equation display]
If service should be required on this calculator, use only a SHARP
servicing dealer, SHARP approved service facility, or SHARP
repair service where available.
•
Pressing @‘ switches between the two editing modes:
insert mode (default); and overwrite mode. A triangular cursor
indicates that an entry will be inserted at the cursor, while the
rectangular cursor indicates to overwrite preexisting data as you
make entries.
Differential/Integral Functions
Differential and integral calculations are only available in the nor-
mal mode. For calculation conditions such as the x value in differ-
ential calculation or the initial point in integral calculation, only
numerical values can be entered and equations such as 22 cannot
be specified. It is possible to reuse the same equation over and
over again and to recalculate by only changing the conditions with-
out re-entering the equation.
Hard Case
DISPLAY
•
•
To insert a number in the insert mode, move the cursor to the
place immediately after where you wish to insert, then make a
desired entry. In the overwrite mode, data under the cursor will
be overwritten by the number you enter.
The mode set will be retained until the next RESET operation.
•
•
Performing a calculation will clear the value in the X memory.
When performing a differential calculation, enter the formula first and
then enter the x value in differential calculation and the minute interval
[Deletion key]
•
To delete a number/function, move the cursor to the number/
function you wish to delete, then press d. If the cursor is
located at the right end of an equation, the d key will function
as a back space key.
(dx). If a numerical value is not specified for minute interval,
x≠0 will be
x
×10–5 and =0 will be 10–5 from the value of the numeric derivative.
x
←Symbol
Equation→
Display
•
When performing an integral calculation, enter the formula first
and then enter a range of integral (a, b) and subintervals (n). If a
numerical value is not specified for subintervals, calculation will
be performed using n=100.
Multi-line Playback Function
Previous equations may be recalled in the normal mode. Equations
also include calculation ending instructions such as “=” and a maxi-
mum of 142 characters can be stored in memory. When the memory
is full, stored equations are deleted in the order of the oldest first.
Pressing [ will display the previous equation. Further pressing
[ will display preceding equations (after returning to the previ-
ous equation, press ] to view equations in order). In addition,
@[ can be used to jump to the oldest equation.
Exponent
Mantissa
Since differential and integral calculations are performed based on
the following equations, correct results may not be obtained, in
certain rare cases, when performing special calculations that con-
tain discontinuous points.
•
•
During actual use, not all symbols are displayed at the same time.
Certain inactive symbols may appear visible when viewed from
a far off angle.
Only the symbols required for the usage under instruction are
shown in the display and calculation examples of this manual.
•
Integral calculation (Simpson’s rule):
b – a
N
N=2n
a≤x≤b
1
3
——
h=
S=—h{ƒ(a)+4{ƒ(a+h)+ƒ(a+3h)+······+ƒ(a+(N–1)h)}
:
Appears when the entire equation cannot be displayed.
Press to see the remaining (hidden) section.
/
•
The multi-line memory is cleared by the following operations:
@c, mode change, RESET, N-base conversion and memory
clear (@∏).
<
/
>
+2{ƒ(a+2h)+ƒ(a+4h)+······+ƒ(a+(N–2)h)}+f(b)}
xy/rθ : Indicates the mode of expression of results in the com-
dx
2
dx
2
plex calculation mode.
f(x+––)–f(x–––)
Differential calculation:
f’(x)=————————
dx
Priority Levels in Calculation
Operations are performed according to the following priority:
: Indicates that data can be visible above/below the
screen. Press [/] to scroll up/down the view.
[When performing integral calculations]
Q Fractions (1 4, etc.) W ∠, engineering prefixes E Functions
2ndF : Appears when @ is pressed.
l
Integral calculations, depending on the integrands and subintervals
included, require longer calculation time. During calculation, “Calculat-
ing!” will be displayed. To cancel calculation, press ª. Note that
there will be greater integral errors when there are large fluctuations in
x
preceded by their argument (x-1, x2, n!, etc.) R Yx,
¿
T Implied
HYP
: Indicates that h has been pressed and the hyper-
bolic functions are enabled. If @H are pressed,
the symbols “2ndF HYP” appear, indicating that inverse
hyperbolic functions are enabled.
multiplication of a memory value (2Y, etc.) Y Functions followed by
their argument (sin, cos, etc.) U Implied multiplication of a function
the integral values during
minute shifting of the inte-
gral range and for periodic
functions, etc., where posi-
tive and negative integral
values exist depending on
the interval.
For the former case, divide
integral intervals as small
as possible. For the latter
A → ï, B → ∫, C → ó, D → ò, E → ô, F → ö
In the binary, pental, octal, and hexadecimal systems, fractional
parts cannot be entered. When a decimal number having a frac-
tional part is converted into a binary, pental, octal, or hexadeci-
mal number, the fractional part will be truncated. Likewise, when
the result of a binary, pental, octal, or hexadecimal calculation
includes a fractional part, the fractional part will be truncated. In
the binary, pental, octal, and hexadecimal systems, negative num-
bers are displayed as a complement.
y
y
x0
x2
b
a
x
x
a
b
x0 x1
x2
x3
x1
x3
Time, Decimal and Sexagesimal Calculations
case, separate the positive and negative values. Following these
tips will allow results of calculations with greater accuracy and will
also shorten the calculation time.
Conversion between decimal and sexagesimal numbers can be
performed, and, while using sexagesimal numbers, conversion to
seconds and minutes notation. The four basic arithmetic opera-
tions and memory calculations can be performed using the
sexagesimal system. Notation for sexagesimal is as follows:
Random Function
The Random function has four settings for use in the normal, statis-
tics, matrix and list modes. (This function cannot be selected while
using the N-Base function.) To generate further random numbers in
succession, press ®. Press ª to exit.
degree
second
•
The generated pseudo-random number series is stored in memory
Y. Each random number is based on a number series.
minute
[Random Numbers]
Coordinate Conversions
A pseudo-random number, with three significant digits from 0 up to
0.999, can be generated by pressing @`0®.
•
Before performing a calculation, select the angular unit.
Y
Y
P (x,y)
P (r,θ)
r
[Random Dice]
y
↔
To simulate a die-rolling, a random integer between 1 and 6 can be
generated by pressing @`1®.
θ
X
X
0
0
x
[Random Coin]
Rectangular coord.
Polar coord.
To simulate a coin flip, 0 (head) or 1 (tail) can be randomly gener-
ated by pressing @`2®.
•
The calculation result is automatically stored in memories X
and Y.
[Random Integer]
•
Value of r or x: X memory
•
Value of θ or y: Y memory
An integer between 0 and 99 can be generated randomly by press-
ing @`3®.
Calculations Using Physical Constants
See the quick reference card and the English manual reverse side.
A constant is recalled by pressing ß followed by the number
of the physical constant designated by a 2-digit number.
The recalled constant appears in the display mode selected with
the designated number of decimal places.
Angular Unit Conversions
Each time @g are pressed, the angular unit changes in sequence.
Memory Calculations
Mode
ANS
M, F1-F4
A-F, X,Y
Physical constants can be recalled in the normal mode (when not
set to binary, pental, octal, or hexadecimal), statistics mode, equa-
tion mode, matrix mode and list mode.
Note: Physical constants and metric conversions are based either
on the 2002 CODATA recommended values or 1995 Edi-
tion of the “Guide for the Use of the International System of
Units (SI)” released by NIST (National Institute of Stand-
ards and Technology) or on ISO specifications.
NORMAL
STAT
EQN
CPLX
MAT
×
×
×
×
×
×
×
×
LIST
: Available
× : Unavailable
[Temporary memories (A-F, X and Y)]
No.
Constant
No.
Constant
Press O and a variable key to store a value in memory.
01 Speed of light in vacuum
02 Newtonian constant of gravitation
03 Standard acceleration of gravity
04 Electron mass
28 Avogadro constant
Press R and a variable key to recall a value from the memory.
29 Molar volume of ideal gas
(273.15 K, 101.325 kPa)
30 Molar gas constant
31 Faraday constant
To place a variable in an equation, press K and a variable key.
[Independent memory (M)]
In addition to all the features of temporary memories, a value can
be added to or subtracted from an existing memory value.
Press ªOM to clear the independent memory (M).
05 Proton mass
06 Neutron mass
07 Muon mass
08 Atomic mass unit-kilogram
relationship
09 Elementary charge
10 Planck constant
32 Von Klitzing constant
33 Electron charge to mass quotient
34 Quantum of circulation
35 Proton gyromagnetic ratio
36 Josephson constant
37 Electron volt
[Last answer memory (ANS)]
The calculation result obtained by pressing = or any other
calculation ending instruction is automatically stored in the last
answer memory. A Matrix/List format result is not stored.
11 Boltzmann constant
12 Magnetic constant
13 Electric constant
38 Celsius Temperature
39 Astronomical unit
40 Parsec
[Formula memories (F1-F4)]
Formulas up to 256 characters in total can be stored in F1 - F4.
(Functions such as sin, etc., will be counted as one letter.) Storing
a new equation in each memory will automatically replace the
existing equation.
14 Classical electron radius
15 Fine-structure constant
16 Bohr radius
41 Molar mass of carbon-12
42 Planck constant over 2 pi
43 Hartree energy
17 Rydberg constant
18 Magnetic flux quantum
19 Bohr magneton
44 Conductance quantum
45 Inverse fine-structure constant
46 Proton-electron mass ratio
47 Molar mass constant
48 Neutron Compton wavelength
49 First radiation constant
50 Second radiation constant
51 Characteristic impedance of
vacuum
Note:
•
Calculation results from the functions indicated below are auto-
matically stored in memories X or Y replacing existing values.
20 Electron magnetic moment
21 Nuclear magneton
22 Proton magnetic moment
23 Neutron magnetic moment
24 Muon magnetic moment
25 Compton wavelength
26 Proton Compton wavelength
27 Stefan-Boltzmann constant
•
•
Random function .......... Y memory
→rθ, →xy ........................ X memory (r or x), Y memory (θ or y)
•
Use of R or K will recall the value stored in memory using
up to 14 digits.
52 Standard atmosphere
Chain Calculations
•
The previous calculation result can be used in the subsequent
calculation. However, it cannot be recalled after entering multiple
instructions or when the calculation result is in Matrix/List format.
When using postfix functions (¿ , sin, etc.), a chain calculation is
possible even if the previous calculation result is cleared by the
use of the ª key.
Metric Conversions
See the quick reference card and the English manual reverse side.
Unit conversions can be performed in the normal mode (when not
set to binary, pental, octal, or hexadecimal), statistics mode, equa-
tion mode, matrix mode and list mode.
•
Fraction Calculations
No.
1
2
Remarks
: inch
: centimeter
: foot
No.
23 fl oz(US): fluid ounce(US)
24 ml : milliliter
25 fl oz(UK): fluid ounce(UK)
Remarks
in
cm
ft
Arithmetic operations and memory calculations can be performed
using fractions, and conversion between a decimal number and a
fraction.
3
4
5
6
7
8
9
m
yd
m
mile
km
: meter
: yard
: meter
: mile
26 ml
27
28 cal
29
30 cal15
31
: milliliter
: Joule
: calorie
: Joule
: Calorie (15n°C)
: Joule
•
If the number of digits to be displayed is greater than 10, the
number is converted to and displayed as a decimal number.
J
J
Binary, Pental, Octal, Decimal, and Hexadecimal
Operations (N-Base)
: kilometer
n mile : nautical mile
J
Conversions can be performed between N-base numbers. The four
basic arithmetic operations, calculations with parentheses and
memory calculations can also be performed, along with the logical
operations AND, OR, NOT, NEG, XOR and XNOR on binary, pental,
octal and hexadecimal numbers.
10
m
: meter
: acre
: square meter
: ounce
: gram
32 calIT
33 hp
: I.T. calorie
: horsepower
: watt
: French horsepower
: watt
11 acre
12 m2
13 oz
34
W
35 ps
14
g
36
37
W
15 lb
16 kg
17 °F
18 °C
19 gal (US) : gallon (US)
20 : liter
21 gal (UK) : gallon (UK)
22 : liter
: pound
Conversion to each system is performed by the following keys:
: kilogram
: Degree Fahrenheit
: Degree Celsius
38 Pa
39 atm
40 Pa
41 (1 mmHg = 1 Torr)
42 Pa
43
: Pascal
: atmosphere
: Pascal
@ê (“ ” appears.), @û (“ ” appears.), @î
(“ ” appears.), @ì (“ ” appears.), @í (“ ”, “ ”, “
”
and “ ” disappear.)
Note: The hexadecimal numbers A – F are entered by pressing
ß, ™, L, ÷, l, and I, and displayed
as follows:
l
: Pascal
l
44
J
: Joule
•
•
If the determinant D = 0, an error occurs.
Calculations Using Engineering Prefixes
Calculation can be executed in the normal mode (excluding N-
base) using the following 9 types of prefixes.
Exponential regression, Logarithmic regression,
If the absolute value of an intermediate result or calculation result
Power regression, and Inverse regression calculation
Statistics of Q and W. In addition, estimate of y for a given x and
estimate of x for a given y. (Since the calculator converts each
formula into a linear regression formula before actual calculation
takes place, it obtains all statistics, except coefficients a and b,
from converted data rather than entered data.)
is 1 × 10100 or more, an error occurs.
•
Coefficients ( a1, etc.) can be entered using ordinary arithmetic
operations.
Prefix
Operation
∑10
∑11
∑12
∑13
∑14
∑15
∑16
∑17
∑18
Unit
103
k
(kilo)
•
•
To clear the entered coefficients, press @c.
Pressing ® when the determinant D is in the display recalls
the coefficients. Each time ® is pressed, a coefficient is
displayed in the order of input, allowing the entered coefficients
to be verified (by pressing @®, coefficients are displayed
in reverse order.) To correct a particular coefficient being dis-
played, enter the correct value and then press ®.
M
G
T
m
µ
n
p
f
(Mega)
(Giga)
(Tera)
(milli)
(micro)
(nano)
(pico)
106
109
1012
10–3
10–6
10–9
10–12
10–15
Quadratic regression calculation
Statistics of Q and W and coefficients a, b, c in the quadratic
regression formula (y = a + bx + cx2). (For quadratic regression
calculations, no correlation coefficient (r) can be obtained.) When
there are two x´ values, press @≠.
QUADRATIC AND CUBIC EQUATION SOLVERS
(femto)
When performing calculations using a, b and c, only one numeric
value can be held.
Quadratic (ax2 + bx + c = 0) or cubic (ax3 + bx2 + cx + d = 0) equation
may be solved using this function.
Modify Function
¯x
Mean of samples (x data)
Q Quadratic equation solver: m22
Calculation results are internally obtained in scientific notation
with up to 14 digits for the mantissa. However, since calculation
results are displayed in the form designated by the display nota-
tion and the number of decimal places indicated, the internal
calculation result may differ from that shown in the display. By
using the modify function, the internal value is converted to match
that of the display, so that the displayed value can be used
without change in subsequent operations.
sx
σx
n
Sample standard deviation (x data)
Population standard deviation (x data)
Number of samples
W Cubic equation solver:
m23
•
•
Press ® after entering each coefficient.
Q
The result will be displayed by pressing ® after entering all
coefficients. When there are more than 2 results, the next solu-
tion will be displayed.
Σx
Sum of samples (x data)
Sum of squares of samples (x data)
Mean of samples (y data)
Σx2
•
•
When the result is an imaginary number, “xy” symbol will appear.
The display can be switched between imaginary and real parts
by pressing @≠.
¯y
sy
σy
Σy
Σy2
Σxy
r
Sample standard deviation (y data)
Population standard deviation (y data)
Sum of samples (y data)
Sum of squares of samples (y data)
Sum of products of samples (x, y)
Correlation coefficient
Solver Function
The x value can be found that reduces an entered equation to “0”.
The results obtained by this function may include a margin of error.
W
•
This function uses Newton's method to obtain an approxima-
tion. Depending on the function (e.g. periodic) or start value, an
error may occur (Error 2) due to there being no convergence to
the solution for the equation.
COMPLEX NUMBER CALCULATIONS
To carry out addition, subtraction, multiplication, and division using
complex numbers, press m3 to select the complex number
mode.
Results of complex number calculations are expressed in two modes:
Q @}: Rectangular coordinate mode (xy appears.)
W @{: Polar coordinate mode (rθ appears.)
Complex number entry
Q Rectangular coordinates
x-coordinate + y-coordinate Ü
or x-coordinate + Ü y-coordinate
W Polar coordinates
a
b
c
Coefficient of regression equation
Coefficient of regression equation
Coefficient of quadratic regression equation
•
•
The value obtained by this function may include a margin of
error. If it is larger than acceptable, recalculate the solution
after changing ‘Start’ and dx values.
Change the ‘Start’ value (e.g. to a negative value) or dx value
(e.g. to a smaller value) if:
•
Use K and R to perform a STAT variable calculation.
Data Entry and Correction
•
•
no solution can be found (Error 2).
more than two solutions appear to be possible (e.g. a cubic
equation).
Entered data are kept in memory until @c or mode selec-
tion. Before entering new data, clear the memory contents.
[Data Entry]
•
to improve the arithmetic precision.
Single-variable data
Data k
•
The calculation result is automatically stored in the X memory.
r Ö θ
r: absolute value
θ: argument
[Performing Solver function]
Q Press m0.
Data
&
frequency
k
(To enter multiples of the same data)
•
•
On selecting another mode, the imaginary part of any complex
number stored in the independent memory (M) will be cleared.
A complex number expressed in rectangular coordinates with the
y-value equal to zero, or expressed in polar coordinates with the
angle equal to zero, is treated as a real number.
Two-variable data
W Input a formula with an x variable.
E Press ∑0.
Data x & Data y k
Data x & Data y & frequency k (To enter multiples
R Input ‘Start’ value and press ®. The default value is “0”.
T Input dx value (minute interval).
Y Press ®.
of the same data x and y.)
•
Up to 100 data items can be entered. With the single-variable
data, a data item without frequency assignment is counted as
one data item, while an item assigned with frequency is stored as
a set of two data items. With the two-variable data, a set of data
items without frequency assignment is counted as two data items,
while a set of items assigned with frequency is stored as a set of
three data items.
•
Press ∑0 to return the complex conjugate of the speci-
fied complex number.
SIMULATION CALCULATION (ALGB)
MATRIX CALCULATIONS
If you have to find a value consecutively using the same formula,
such as plotting a curve line for 2x2 + 1, or finding the variable for
2x + 2y =14, once you enter the equation, all you have to do is to
specify the value for the variable in the formula.
Usable variables: A-F, M, X and Y
Unusable functions: Random function
This function enables the saving of up to 4 matrices (4 rows x 4
columns) for calculations. Press m4 to enter the matrix mode.
•
Matrix data must be entered prior to making calculations. Press-
[Data Correction]
ing [/] will display the matrix edit buffer along with
.
Correction prior to pressing k immediately after a data entry:
Enter the value of each item (‘ROW’, ‘COLUMN’, and then each
element, e.g. ‘MAT1,1’) and press k after each. After enter-
ing all items, press ª, then press °2 and specify
matA-D to save the data.
Delete incorrect data with ª, then enter the correct data.
•
Simulation calculations can only be executed in the normal
mode.
Correction after pressing k:
Use [] to display the data previously entered.
Press ] to display data items in ascending (oldest first)
order. To reverse the display order to descending (latest first),
press the [ key.
•
Calculation ending instructions other than= cannot be used.
•
To edit data saved in matA-D, press °1 and specify
matA-D to recall the data to the matrix edit buffer. After editing,
press ª, then press °2 and specify matA-D to save
the data.
Performing Calculations
Q Press m0.
Each item is displayed with ‘Xn=’, ‘Yn=’, or ‘Nn=’ (n is the sequen-
tial number of the data set).
W Input a formula with at least one variable.
E Press @≤.
•
•
Before performing calculations, press ª to close the matrix
edit buffer.
Display the data item to modify, input the correct value, then
press k. Using &, you can correct the values of the data
set all at once.
R Variable input screen will appear. Input the value of the flashing
variable, then press ® to confirm. The calculation result will
be displayed after entering the value for all used variables.
When results of calculations are in the matrix format, the matrix
edit buffer with those results will be displayed. (At this time, you
cannot return to the equation.) To save the result in matA-D,
press ª, then press °2 and specify matA-D.
Since there is only one matrix edit buffer, the previous data will
be overwritten by the new calculation.
In addition to the 4 arithmetic functions (excluding divisions be-
tween matrices), x3, x2, and x–1, the following commands are
available:
•
•
To delete a data set, display an item of the data set to delete,
then press @J. The data set will be deleted.
To add a new data set, press ª and input the values, then
press k.
•
•
•
Only numerical values are allowed as variables. Input of
formulas is not permitted.
•
•
Upon completing the calculation, press @≤ to per-
form calculations using the same formula.
Variables and numerical values stored in the memories will
be displayed in the variable input screen. To change a
numerical value, input the new value and press ®.
Performing simulation calculation will cause memory loca-
tions to be overwritten with new values.
Statistical Calculation Formulas
Type
Linear
Exponential
Logarithmic
Power
Regression formula
dim(matrix name,
row,column)
Returns a matrix with dimensions changed as
specified.
•
y = a + bx
y = a • ebx
y = a + b • ln x
y = a • xb
fill(value,row,column) Fills each element with a specified value.
cumul matrix name
Returns the cumulative matrix.
STATISTICAL CALCULATIONS
aug(matrix name,
matrix name)
Appends the second matrix to the first matrix as new
columns. The first and second matrices must have
the same number of rows.
Press m1 to select the statistics mode. The seven statisti-
cal calculations listed below can be performed. After selecting the
statistics mode, select the desired sub-mode by pressing the
number key corresponding to your choice.
1
y = a + b —
x
Inverse
Quadratic
y = a + bx + cx2
identity value
Returns the identity matrix with specified value of
rows and columns.
In the statistical calculation formulas, an error will occur when:
To change statistical sub-mode, reselect statistics mode (press
rnd_mat(row,column) Returns a random matrix with specified values of
•
The absolute value of the intermediate result or calculation result
m1), then select the required sub-mode.
rows and columns.
is equal to or greater than 1 × 10100
.
0 (SD)
: Single-variable statistics
det matrix name
Returns the determinant of a square matrix.
•
•
•
The denominator is zero.
1 (LINE) : Linear regression calculation
2 (QUAD) : Quadratic regression calculation
3 (EXP) : Exponential regression calculation
4 (LOG) : Logarithmic regression calculation
5 (PWR) : Power regression calculation
trans matrix name
Returns the matrix with the columns transposed to
rows and the rows transposed to columns.
An attempt is made to take the square root of a negative number.
No solution exists in the quadratic regression calculation.
mat→list
(∑5)
Creates lists with elements from the left column of each
matrix. (matA→L1, matB→L2, matC→L3, matD→L4)
Mode changes from matrix mode to list mode.
Normal Probability Calculations
•
P(t), Q(t), and R(t) will always take positive values, even when
t<0, because these functions follow the same principle used
when solving for an area.
6 (INV)
: Inverse regression calculation
matA→list
(∑6)
Creates lists with elements from each column of the
matrix. (matA→L1, L2, L3, L4)
Mode changes from matrix mode to list mode.
The following statistics can be obtained for each statistical calcu-
lation (refer to the table below):
Values for P(t), Q(t), and R(t) are given to six decimal places.
Single-variable statistical calculation
SIMULTANEOUS LINEAR EQUATIONS
LIST CALCULATIONS
Statistics of Q and value of the normal probability function
Simultaneous linear equation with two unknowns (2-VLE) or with
three unknowns (3-VLE) may be solved using this function.
Q 2-VLE: m20
This function enables the saving of up to 4 lists of 16 elements for
Linear regression calculation
Statistics of Q and W and, in addition, estimate of y for a given
x (estimate y´) and estimate of x for a given y (estimate x´)
calculations. Press m5 to enter the list mode.
•
List data must be entered prior to making calculations. Pressing
W 3-VLE: m21
[/] will display the list edit buffer along with
. Enter
the value of each item (‘SIZE’, and then each element, e.g.
‘LIST1’) and press k after each. After entering all items,
press ª, then press °2 and specify L1-4 to save the
data.
To edit data saved in L1-4, press °1 and specify L1-4 to
recall the data to the list edit buffer. After editing, press ª,
then press °2 and specify L1-4 to save the data.
Before performing calculations, press ª to close the list edit
buffer.
•
Calculation ranges
10–99 9.999999999×1099 and 0.
~
If the absolute value of an entry or a final or intermediate result of
a calculation is less than 10–99, the value is considered to be 0 in
calculations and in the display.
•
BATTERY REPLACEMENT
•
•
Notes on Battery Replacement
Improper handling of batteries can cause electrolyte leakage or
explosion. Be sure to observe the following handling rules:
•
•
•
•
When results of calculations are in the list format, the list edit
buffer with those results will be displayed. (At this time, you
cannot return to the equation.) To save the result in L1-4, press
ª, then press °2 and specify L1-4.
Replace both batteries at the same time.
Do not mix new and old batteries.
Make sure the new batteries are the correct type.
When installing, orient each battery properly as indicated in the
calculator.
Batteries are factory-installed before shipment, and may be
exhausted before they reach the service life stated in the speci-
fications.
•
•
Since there is only one list edit buffer, the previous data will be
overwritten by the new calculation.
In addition to the 4 arithmetic functions, x3, x2, and x–1, the follow-
ing commands are available:
•
sortA list name
sortD list name
dim(list name,size)
fill(value,size)
Sorts list in ascending order.
Sorts list in descending order.
Notes on erasure of memory contents
Returns a list with size changed as specified.
Enter the specified value for all items.
Sequentially cumulates each item in the list.
When the battery is replaced, the memory contents are erased.
Erasure can also occur if the calculator is defective or when it is
repaired. Make a note of all important memory contents in case
accidental erasure occurs.
cumul list name
df_list list name
Returns a new list using the difference between
adjacent items in the list.
When to Replace the Batteries
If the display has poor contrast or nothing appears on the display
even when ª is pressed in dim lighting, it is time to replace
the batteries.
aug(list name,list name)
min list name
Returns a list appending the specified lists.
Returns the minimum value in the list.
Returns the maximum value in the list.
Returns the mean value of items in the list.
Returns the median value of items in the list.
Returns the sum of items in the list.
max list name
mean list name
med list name
sum list name
prod list name
stdDv list name
vari list name
Cautions
•
Fluid from a leaking battery accidentally entering an eye could
result in serious injury. Should this occur, wash with clean
water and immediately consult a doctor.
Returns the multiplication of items in the list.
Returns the standard deviation of the list.
Returns the variance of the list.
•
•
Should fluid from a leaking battery come in contact with your
skin or clothes, immediately wash with clean water.
If the product is not to be used for some time, to avoid damage
to the unit from leaking batteries, remove them and store in a
safe place.
o_prod(list name,list name) Returns the outer product of 2 lists (vectors).
i_prod(list name,list name) Returns the inner product of 2 lists (vectors).
abs list name
Returns the absolute value of the list (vector).
Creates matrices with left column data from
•
•
Do not leave exhausted batteries inside the product.
Do not fit partially used batteries, and be sure not to mix
batteries of different types.
list→mat
(∑5)
each list. (L1→matA, L2→matB, L3→matC,
L4→matD)
Mode changes from list mode to matrix mode.
•
•
Keep batteries out of the reach of children.
Exhausted batteries left in the calculator may leak and damage
the calculator.
list→matA
(∑6)
Creates a matrix with column data from each
list. (L1, L2, L3, L4→matA)
Mode changes from list mode to matrix mode.
•
•
Explosion risk may be caused by incorrect handling.
Do not throw batteries into a fire as they may explode.
Replacement Procedure
ERROR AND CALCULATION RANGES
1. Turn the power off by pressing @F.
Errors
2. Remove the two screws. (Fig. 1)
An error will occur if an operation exceeds the calculation ranges,
or if a mathematically illegal operation is attempted. When an error
occurs, pressing < (or >) automatically moves the cursor
back to the place in the equation where the error occurred. Edit the
equation or press ª to clear the equation.
3. Slide the battery cover slightly and lift it to remove.
4. Remove the used batteries by prying them out with a ball-point
pen or other similar pointed device. (Fig. 2)
5. Install two new batteries. Make sure the “+” side is facing up.
6. Replace the cover and screws.
7. Press the RESET switch (on the back).
Error Codes and Error Types
Syntax error (Error 1):
An attempt was made to perform an invalid operation.
•
Make sure that the display appears as shown below. If the
display does not appear as shown, remove the batteries, rein-
stall them and check the display once again.
•
Ex. 2 @{
(Fig. 1)
(Fig. 2)
Calculation error (Error 2):
•
•
•
The absolute value of an intermediate or final calculation result equals
or exceeds 10100
.
An attempt was made to divide by 0 (or an intermediate calculation
resulted in zero).
The calculation ranges were exceeded while performing calculations.
Depth error (Error 3):
Automatic Power Off Function
This calculator will turn itself off to save battery power if no key is
pressed for approximately 10 minutes.
•
The available number of buffers was exceeded. (There are 10 buffers*
for numeric values and 24 buffers for calculation instructions in the
normal mode).
*5 buffers in other modes, and 1 buffer for Matrix/List data.
Data items exceeded 100 in the statistics mode.
•
SPECIFICATIONS
Equation too long (Error 4):
The equation exceeded its maximum input buffer (142 characters).
An equation must be shorter than 142 characters.
Calculations:
Scientific calculations, complex number
calculations, equation solvers, statistical
calculations, etc.
•
Equation recall error (Error 5):
Internal calculations: Mantissas of up to 14 digits
•
The stored equation contains a function not available in the mode
used to recall the equation. For example, if a numerical value with
numbers other than 0 and 1 is stored as a decimal, etc., it cannot be
recalled when the calculator is set to binary.
Pending operations:
24 calculations 10 numeric values in the
normal mode (5 numeric values in other
modes, and 1 numeric value for Matrix/
List data.)
Memory over error (Error 6):
Power source:
Built-in solar cells
•
Equation exceeded the formula memory buffer (256 characters in total
in F1 - F4).
3 V ¶ (DC):
Backup batteries
Invalid error (Error 7):
Matrix/list definition error or entering an invalid value.
(Alkaline batteries (LR44 or equivalent) × 2)
•
Operating temperature: 0°C – 40°C (32°F – 104°F)
External dimensions: 79.6 mm (W) × 154.5 mm (D) × 13.2 mm (H)
3-1/8” (W) × 6-3/32” (D) × 17/32” (H)
Dimension error (Error 8):
Matrix/list dimensions inconsistent while calculation.
•
Invalid DIM error (Error 9):
Size of matrix/list exceeds calculation range.
Weight:
Approx. 97g (0.22 lb)
(Including batteries)
•
Accessories:
Batteries × 2 (installed), operation manual,
quick reference card and hard case
No define error (Error 10):
Undefined matrix/list used in calculation.
•
Calculation Ranges
FOR MORE INFORMATION ABOUT
SCIENTIFIC CALCULATOR
•
Within the ranges specified, this calculator is accurate to
1
of the least significant digit of the mantissa. However, a
calculation error increases in continuous calculations due
Visit our Web site.
to accumulation of each calculation error. (This is the same
x
for yx,
, n!, ex, ln, Matrix/List calculations, etc., where
¿
continuous calculations are performed internally.)
Additionally, a calculation error will accumulate and become
larger in the vicinity of inflection points and singular points
of functions.
SHARP CORPORATION
ENGLISH
• • • •
5
7
KRO;:?≥∆˚¬
@Ht( 5
tanh–1— =
/ 7 )=
0.895879734
2.995732274
1.698970004
20.08553692
50.11872336
ª 8 * 2 OM
24 /KM=
KM* 5 =
16.
24÷(8×2)=
(8×2)×5=
1.5
80.
ln 20 =
I 20 =
l 50 =
@e 3 =
@¡ 1.7 =
EL-506W
EL-546W
log 50 =
e3 =
ªOM
0.
450.
250.
35.
$150×3:M1
150 * 3 ;
CALCULATION EXAMPLES
ANWENDUNGSBEISPIELE
EXEMPLES DE CALCUL
EJEMPLOS DE CÁLCULO
EXEMPLOS DE CÁLCULO
ESEMPI DI CALCOLO
REKENVOORBEELDEN
PÉLDASZÁMÍTÁSOK
PŘÍKLADY VÝPOČTŮ
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$1=¥110
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110 OY
110.
241.
302’500.
8–2 – 34 × 52 =
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1
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3
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r=3cm (r→Y)
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512.
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28.27433388
83 =
8 ÷=
24
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4+6
24 /( 4 + 6 )=
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@⁄ 49 - 4 @$
3 *K?+ 60 /
81 =
4.
3.
3×(A)+60÷(A)=
K?=
32.2
3
¿27 =
@# 27 =
4 @!=
10 @q 3 =
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120 / 400 @%
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37.69911184
5C2 =
500×25%=
120÷400=?%
125.
30.
6+4=ANS
ANS+5
ª 6 + 4 =
10.
15.
500+(500×25%)= 500 + 25 @%
400–(400×30%)= 400 - 30 @%
625.
280.
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CONTOH-CONTOH PENGHITUNGAN
CONTOH-CONTOH PERHITUNGAN
CAÙC VÍ DUÏ PHEÙP TÍNH
8×2=ANS
8 * 2 =
16.
256.
ANS2
L=
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
44+37=ANS
44 + 37 =
81.
9.
√ANS=
@⁄=
[]
13(5+2)=
23×5+2=
33×5+3×2=
→1
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21.
17.
21.
21.
17.
21.
17.
\|
3 * 5 + 2 =
1
2
4
b
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4 \ 3 =
\
c
3
@[
]
4
5
6 *
l
4.833333333
29 6
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2
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10
3
=
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4.641588834
5
7
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—
5
=
7 \ 5 ™ 5 =
16807 3125
l
(
(
)
1
3
100000÷3=
[NORM1]
→[FIX]
[TAB 2]
→[SCI]
—
1 \ 8 ™ 1 \ 3
1
—
=
)
ª 100000 / 3 = 33’333.33333
=
1
2
l
8
”10
”2 2
33’333.33333
33’333.33
64
—— =
225
@⁄ 64 \ 225 =
8
8
15
l
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”12
”13
3.33 ×10 04–
23
( 2 ™ 3 ) \
→[ENG]
→[NORM1]
33.33 ×10 03–
— =
34
( 3 ™ 4 ) =
81
l
33’333.33333
θ = sin–1 x, θ = tan–1 x
θ = cos
x
–1
1.2
3÷1000=
—– =
2.3
1.2 \ 2.3 =
12 23
l
DEG
RAD
–90 ≤ θ ≤ 90
0 ≤ θ ≤ 180
[NORM1]
→[NORM2]
→[NORM1]
ª 3 / 1000 =
”14
0.003
3. ×10 –03
0.003
π
π
1°2’3”
——– =
2
– — ≤ θ ≤ —
0 ≤ θ ≤ π
1 o 2 o 3 \ 2 =
1 E 3 \ 2 E 3 =
0°31’1.5”
2
2
”13
1×103
GRAD
–100 ≤ θ ≤ 100
0 ≤ θ ≤ 200
——– =
2×103
1
2
l
+-*/()
E
A = 7
ª 7 OA
4 \KA=
7.
7
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45+285÷3=
ª 45 + 285 / 3 =
140.
4
— =
4
l
d/dx (x4 – 0.5x3 + 6x2) ªKˆ™ 4 - 0.5 K
A
18+6
=
( 18 + 6 )/
x=2
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@Å 2 ®®
2
15–8
( 15 - 8 =
3.428571429
–90.
1.25 + — = [a.xxx]
1.25 + 2 \ 5 =
1.65
13 20
5
dx=0.00002
50.
b
→[a—]
c
\
1
42×(–5)+120=
42 *
5 + 120 =
l
l
x=3
® 3 ® 0.001 ®
130.5000029
1
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)
*
5
6
dx=0.001
* 4
5
6 = 4—
l
l
(5×103)÷(4×10–3)= 5 E 3 / 4 E
∫
82 (x2 – 5)dx
ªKˆL- 5
è 2 ® 8 ®®
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3 =
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n=100
n=10
138.
138.
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àá
DEC(25)→BIN
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11001.b
g
34+57=
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91.
102.
HEX(1AC)
→BIN
→PEN
→OCT
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@ì 1AC
@ê
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@î
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110101100.b
3203.P
654.0
90°→ [rad]
→ [g]
→ [°]
ª 90 @g
@g
1.570796327
100.
68×25=
68×40=
68 * 25 =
1’700.
2’720.
68 * 40 =
@g
90.
428.
sin–10.8 = [°]
→ [rad]
→ [g]
@S 0.8 =
53.13010235
0.927295218
59.03344706
53.13010235
sutSUTVhH
Ile¡•L÷⁄™
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@g
BIN(1010–100)
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ã 111 =
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HEX(1FF)+
OCT(512)=
HEX(?)
@ì 1FF @î+
sin60[°]=
ªs 60 =
0.866025403
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4
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0.707106781
50.
2FEC–
2C9E=(A)
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tan–11=[g]
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2000 -
1901 ;
RM
34E.H
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6FF.H
A4d.H
(cosh 1.5 +
sinh 1.5)2 =
ª(hu 1.5 +h
s 1.5 )L=
20.08553692
• • • •
• • • •
• • • •
k&~£pnzw^
¢PZWvrab©
xy≠° (→t, P(, Q(, R()
1011 AND
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101 = (BIN)
101 =
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@ì 5A ä C3 =
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DATA
NOT 10110 =
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1111101001.b
95
80
80
75
75
75
50
m10
95 k
0.
1.
2.
3.
4.
5.
24 XOR 4 = (OCT)
@î 24 à 4 =
20.0
80 k
k
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2D = (HEX)
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–159.
75 & 3 k
50 k
@í
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Rp
Rn
Rz
Rw
R£
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75.71428571
12.37179148
7.
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41’200.
13.3630621
178.5714286
o_° (→sec, →min)
12°39’18.05”
σx=
n=
ª 12 o 39 o 18.05
Σx=
Σx2=
sx=
→[10]
@_
12.65501389
123°40’40.8”
123.678→[60]
123.678 @_
sx2=
3h30m45s +
6h45m36s = [60]
3 o 30 o 45 + 6 o
45 o 36 =
10°16’21.”
–
(95–x)
( 95 -K~)
/K£* 10
+ 50 =
1234°56’12” +
0°0’34.567” = [60]
1234 o 56 o 12 +
×10+50=
sx
0 o 0 o 34.567 =
1234°56’47.”
64.43210706
3h45m –
1.69h = [60]
3 o 45 - 1.69 =
@_
2°3’36.”
0.884635235
86’400.
x = 60 → P(t) ?
t = –0.5 → R(t) ?
°1 60 °0)= 0.102012
°3 0.5
)=
0.691463
sin62°12’24” = [10]
24°→[ ” ]
s 62 o 12 o 24=
24 o°2
0 o 0 o 1500 °3
x
2
2
y
5
5
m11
2 & 5 k
k
0.
1.
2.
3.
4.
1500”→[ ’ ]
25.
12 24
21 40
21 40
21 40
15 25
12 & 24 k
21 & 40 & 3 k
15 & 25 k
Ra
{},≠
5.
ª 6 @, 4
1.050261097
1.826044386
0.995176343
8.541216597
15.67223812
x = 6
y = 4
r =
θ = [°]
@{[r]
7.211102551
33.69006753
7.211102551
Rb
→
@≠[θ]
Rr
@≠[r]
R£
R¢
14 @, 36
@}[x]
@≠[y]
@≠[x]
r = 14
θ = 36[°]
x =
y =
11.32623792
8.228993532
11.32623792
→
x=3 → y′=?
y=46 → x′=?
3 @y
6.528394256
24.61590706
46 @x
x
y
m12
12 & 41 k
8 & 13 k
5 & 2 k
23 & 200 k
15 & 71 k
Ra
0.
1.
2.
3.
4.
12 41
ß
V0 = 15.3m/s
8
5
13
2
23 200
15 71
ª 15.3 * 10 + 2 @•*
t = 10s
1
ß 03 * 10 L=
643.3325
V0t+ — gt2 = ?m
2
5.
5.357506761
–3.120289663
0.503334057
Rb
R©
¥
125yd = ?m
ª 125 @¥ 5 =
114.3
x=10 → y′=?
y=22 → x′=?
10 @y
22 @x
@≠
24.4880159
9.63201409
–3.432772026
9.63201409
∑ (k, M, G, T, m, Ì, n, p, f)
100m×10k=
@≠
100 ∑14*
10 ∑10=
1’000.
k[]
DATA
30
j”
5÷9=ANS
ANS×9=
[FIX,TAB=1]
m10
30 k
0.
1.
2.
3.
40
40
50
ª”10”2 1
5 / 9 =
40 & 2 k
50 k
0.6
5.0
* 9 =*1
↓
5 / 9 =@j
0.6
5.4
DATA
* 9 =*2
30
45
45
45
60
]]]
45 & 3 k
]
”13
X2= 45.
N2= 3.
1
*
*
5.5555555555555×10–1×9
0.6×9
2
] 60 k
X3= 60.
∑ (SOLV)
sin x–0.5
Start= 0
ªsKˆ- 0.5
∑0 0 ®®
® 180 ®®
Σx2 – nx2
30.
150.
Σx
σx =
Σx = x + x + ··· + x
n
x =
n
n
Start= 180
1
2
Σx2 – nx2
n – 1
Σx2 = x 2 + x 2 + ··· + x
n
2
1
2
sx =
y =
≤
Σy2 – ny2
m0
Σy
n
σy =
f(x) = x3–3x2+2
Kˆ™ 3 - 3 K
ˆL+ 2 @≤
n
Σxy = x y + x y + ··· + x y
1
1
2
2
n
n
x = –1
x = –0.5
1
®
–2.
1.125
Σy2 – ny2
n – 1
Σy = y + y + ··· + y
1
2
n
sy =
2
Σy2 = y 2 + y 2 + ··· + y
n
@≤ 0.5
®
1
2
A2+B2
@⁄(KAL+
KBL)@≤
A = 2, B = 3
A = 2, B = 5
2 ® 3 ®
3.605551275
5.385164807
@≤® 5 ®
• • • •
• • • •
y
@{ 8 Ö 70 + 12 Ö 25
stdDv L1 = 2.516611478
ª∑46∑00=
ª∑47∑00=
A
= [r]
18.5408873i
r
r1
vari L1 = 6.333333333
∠
@≠ [θ]
42.76427608i
B
θ
θ1
r2
θ2
o_prod(L1,L2) = {–24 –4 19}
ª∑48∑00
x
@,∑01)=
r1 = 8, θ1 = 70°
r2 = 12, θ2 = 25°
↓
i_prod(L1,L2) = –29
ª∑49∑00
@,∑01)=
ª∑4A∑01=
r = ?, θ = ?°
abs L2 = 5.099019514
(1 + i)
↓
r = ?, θ = ?°
@} 1 +Ü=
@{ [r]
1.
i
list → matA matA: 2 –3
list → matA matA: 7 –1
list → matA matA: 4 –4
1.414213562
i
ª∑6
∠
@≠ [θ]
45.
i
@}( 2 - 3 Ü)L
(2 – 3i)2 =
= [x]
–5.
12.
i
i
–
@≠ [y]
1
( 1 +Ü)@•= [x] 0.5
Function
Funktion
Fonction
Función
Função
Funzioni
Functie
Függvény
Funkce
Funktion
Funktio
Dynamic range
zulässiger Bereich
Plage dynamique
Rango dinámico
Gama dinâmica
i
i
—— =
1 + i
x – x
t = ––––
σx
–
Standardization conversion formula
Standard Umrechnungsformel
@≠ [y]
0.5
CONJ(5+2i) =
∑0( 5 + 2 Ü)= [x] 5.
i
i
Formule de conversion de standardisation
Fórmula de conversión de estandarización
Fórmula de conversão padronizada
Formula di conversione della standardizzazione
Standaardisering omzettingsformule
Standard átváltási képlet
–
@≠ [y]
2.
Campi dinamici
Rekencapaciteit
Megengedett számítási tartomány
Dynamický rozsah
Definitionsområde
Dynaaminen ala
m (MAT)
m4
Vzorec pro přepočet rozděleníꢀ
1 2
3 4
] 2 k 2 k 1 k 2 k
3 k 4 k
→ matA
Omvandlingsformel för standardisering
Normituksen konversiokaava
ª∑20
îÛÌ͈Ëfl
Funktion
ÑË̇Ï˘ÂÒÍËÈ ‰Ë‡Ô‡ÁÓÌ
Dynamikområde
3 1
2 6
îÓÏÛ· Òڇ̉‡ÚËÁÓ‚‡ÌÌÓ„Ó ÔÂÓ·‡ÁÓ‚‡ÌËfl
Omregningsformel for standardisering
→ matB
] 2 k 2 k
3 k 1 k 2 k 6 k
ª∑21
7 13
17 27
matA × matB =
ª∑00*∑01=
Fungsi
Fungsi
Haøm soá
Julat dinamik
Kisaran dinamis
Giôùi haïn Ñoäng
Rumus penukaran pemiawaian
Rumus konversi standarisasi
Coâng thöùc bieán ñoåi chuaån hoùaꢀ
–2
1
matA–1
=
ª∑00@•=
1.5 –0.5
DEG: | x | < 1010
m (2-VLE)
dim(matA,3,3) = 1 2 0
dim(matA,3,3) = 3 4 0
dim(matA,3,3) = 0 0 0
(tan x : | x | ≠ 90 (2n–1))*
ª∑30∑00
a1x + b1y = c1
a2x + b2y = c2
a1 b1
a2 b2
π
sin x, cos x,
D =
RAD:
| x | < —– × 1010
@, 3 @, 3 )=
180
π
2
tan x
(tan x : | x | ≠ — (2n–1))*
10
fill(5,3,3) = 5 5 5
fill(5,3,3) = 5 5 5
fill(5,3,3) = 5 5 5
GRAD: | x | < —– × 1010
m20
ª∑31 5 @,
9
2x + 3y = 4
5x + 6y = 7
2 ® 3 ® 4 ®
5 ® 6 ® 7
® [x]
(tan x : | x | ≠ 100 (2n–1))*
3 @, 3 )=
sin–1x, cos–1x
tan–1x, 3
| x | ≤ 1
| x | < 10100
10–99 ≤ x < 10100
x = ?
y = ?
det(D) = ?
–1.
2.
–3.
1 2
cumul matA =
4 6
x
¿
ª∑32∑00=
® [y]
In x, log x
® [det(D)]
• y > 0: –10100 < x log y < 100
1 2 3 1 ª∑33∑00
aug(matA,matB) =
• y = 0: 0 < x < 10100
3 4 2 6 @,∑01)=
x
y
• y < 0: x = n
m (3-VLE)
1
x
identity 3 = 1 0 0
identity 3 = 0 1 0
identity 3 = 0 0 1
(0 < l x l < 1: — = 2n–1, x ≠ 0)*,
a1x + b1y + c1z = d1
a2x + b2y + c2z = d2
a3x + b3y + c3z = d3
a1 b1 c1
a2 b2 c2
a3 b3 c3
ª∑34 3 =
–10100 < x log | y | < 100
D =
1
x
• y > 0: –10100 < — log y < 100 (x ≠ 0)
rnd_mat(2,3)
det matA = –2
ª∑35 2 @, 3 )=
ª∑40∑00=
• y = 0: 0 < x < 10100
m21
x
¿y
• y < 0: x = 2n–1
x + y – z = 9
6x + 6y – z = 17
14x – 7y + 2z = 42
1 ® 1 ® 1
6 ® 6 ® 1
14 ® 7
® 9 ®
1
x
(0 < | x | < 1 : — = n, x ≠ 0)*,
–10100 < — log | y | < 100
® 17 ®
3 2
trans matB =
1 6
1
x
ª∑41∑01=
ª∑5
® 2 ® 42
x = ?
® [x]
3.238095238
–1.638095238
–7.4
x
e
–10100 < x ≤ 230.2585092
–10100 < x < 100
L1: {1 3}
mat → list
y = ?
z = ?
det(D) = ?
® [y]
x
10
L2: {3 2}
® [z]
sinh x, cosh x,
tanh x
sinh–1 x
cosh–1 x
tanh–1 x
x2
® [det(D)]
105.
| x | ≤ 230.2585092
m (LIST)
| x | < 1050
1 ≤ x < 1050
| x | < 1
| x | < 1050
m (QUAD, CUBIC)
m5
2, 7, 4 → L1
] 3 k 2 k 7 k 4 k
ª∑20
] 3 k
m22
3 ® 4 ®
®
3x2 + 4x – 95 = 0
x1 = ?
95
–3, –1, –4 → L2
x3
| x | < 2.15443469 × 1033
5.
–6.333333333
5.
3 k
1 k
4 k
x
x–1
0 ≤ x < 10100
¿
x2 = ?
®
| x | < 10100 (x ≠ 0)
0 ≤ n ≤ 69*
0 ≤ r ≤ n ≤ 9999999999*
ª∑21
@®
n!
L1+L2 = {–1 6 0}
sortA L1 = {2 4 7}
sortD L1 = {7 4 2}
ª∑00+∑01=
ª∑30∑00=
ª∑31∑00=
m23
5x3 + 4x2 + 3x + 7 = 0 5 ® 4 ® 3 ® 7
nPr
nCr
n!
—— < 10100
(n-r)!
x1 = ?
x2 = ?
®
–1.233600307
i
0 ≤ r ≤ n ≤ 9999999999*
®
0.216800153
i
ª∑32∑00
0 ≤ r ≤ 69
+
@≠
®
1.043018296
dim(L1,5) = {2 7 4 0 0}
fill(5,5) = {5 5 5 5 5}
i
@, 5 )=
n!
x3 = ?
0.216800153
i
—— < 10100
(n-r)!
–
ª∑33 5 @,
@≠
1.043018296
i
↔
DEG, D°M’S
0°0’0.00001” ≤ | x | < 10000°
x2 + y2 < 10100
5 )=
x, y → r, θ
cumul L1 = {2 9 13}
df_list L1 = {5 –3}
ª∑34∑00=
ª∑35∑00=
m (CPLX)
0 ≤ r < 10100
DEG: | θ | < 1010
m3
π
r, θ → x, y
RAD:
| θ | < —– × 1010
(12–6i) + (7+15i) –
12 - 6 Ü+ 7 + 15 Ü-
aug(L1,L2) = {2 7 4 –3 –1 –4} ª∑36∑00
180
(11+4i) =
( 11 + 4 Ü)= [x]
8.
5.
i
i
@,∑01)=
10
GRAD : | θ | < — × 1010
+
@≠ [y]
9
min L1 = 2
ª∑40∑00=
ª∑41∑00=
ª∑42∑00=
ª∑43∑00=
ª∑44∑00=
ª∑45∑00=
DEG→RAD, GRAD→DEG: | x | < 10100
@≠ [x]
8.i
max L1 = 7
DRG |
π
98
—
RAD→GRAD: | x | <
× 10
6×(7–9i) ×
(–5+8i) =
6 *( 7 - 9 Ü)*
2
mean L1 = 4.333333333
med L1 = 4
( 5
+ 8 Ü)= [x] 222.
i
i
(A+Bi)+(C+Di)
| A + C | < 10100, | B + D | < 10100
| A – C | < 10100, | B – D | < 10100
+
@≠ [y]
606.
(A+Bi)–(C+Di)
(AC – BD) < 10100
16×(sin30°+
icos30°)÷(sin60°+
icos60°)=
16 *(s 30 +
sum L1 = 13
prod L1 = 56
• • • •
(A+Bi)×(C+Di)
(AD + BC) < 10100
Üu 30 )/(s 60 +
Üu 60 )= [x]
13.85640646
i
i
• • • •
+
@≠ [y]
8.
• • • •
• • • •
Endast svensk version/For Sweden only:
AC + BD
C2 + D2
< 10100
< 10100
Miljöskydd
Denna produkt drivs av batteri.
Vid batteribyte skall följande iakttagas:
(A+Bi)÷(C+Di)
BC – AD
C2 + D2
•
Det förbrukade batteriet skall inlämnas till er lokala handlare
eller till kommunal miljöstation för återinssamling.
Kasta ej batteriet i vattnet eller i hushållssoporna. Batteriet
får ej heller utsättas för öppen eld.
C2 + D2 ≠ 0
→DEC
→BIN
→PEN
→OCT
→HEX
AND
OR
XOR
XNOR
DEC : | x | ≤ 9999999999
BIN : 1000000000 ≤ x ≤ 1111111111
0 ≤ x ≤ 111111111
•
PEN : 2222222223 ≤ x ≤ 4444444444
0 ≤ x ≤ 2222222222
OCT : 4000000000 ≤ x ≤ 7777777777
0 ≤ x ≤ 3777777777
HEX : FDABF41C01 ≤ x ≤ FFFFFFFFFF
0 ≤ x ≤ 2540BE3FF
OPMERKING: ALLEEN VOOR NEDERLAND/
NOTE: FOR NETHERLANDS ONLY
BIN : 1000000000 ≤ x ≤ 1111111111
0 ≤ x ≤ 111111111
PEN : 2222222223 ≤ x ≤ 4444444444
0 ≤ x ≤ 2222222221
OCT : 4000000000 ≤ x ≤ 7777777777
0 ≤ x ≤ 3777777777
HEX : FDABF41C01 ≤ x ≤ FFFFFFFFFF
0 ≤ x ≤ 2540BE3FE
BIN : 1000000001 ≤ x ≤ 1111111111
0 ≤ x ≤ 111111111
PEN : 2222222223 ≤ x ≤ 4444444444
0 ≤ x ≤ 2222222222
OCT : 4000000001 ≤ x ≤ 7777777777
0 ≤ x ≤ 3777777777
HEX : FDABF41C01 ≤ x ≤ FFFFFFFFFF
0 ≤ x ≤ 2540BE3FF
•
•
•
•
•
•
•
•
•
•
Physical Constants and Metric Conversions are shown in the
tables.
Physikalischen Konstanten und metriche Umrechnungen sind
in der Tabelle aufgelistet.
Les constants physiques et les conversion des unités sont
indiquées sur les tableaux.
Las constants fisicas y conversiones métricas son mostradas
en las tables.
Constantes Fisicas e Conversões Métricas estão mostradas
nas tablelas.
La constanti fisiche e le conversioni delle unità di misura
vengono mostrate nella tabella.
NOT
NEG
De natuurconstanten en metrische omrekeningen staan in de
tabellen hiernaast.
A fizikai konstansok és a metrikus átváltások a táblázatokban
találhatók.
* n, r: integer / ganze Zahlen / entier / entero / inteiro / intero /
Fyzikální konstanty a převody do metrické soustavy jsou
uvedeny v tabulce.
geheel getal / egész számok / celé číslo / heltal /
kokonaisluku / ˆÂÎ˚ / heltal /
/
/
/
Fysikaliska konstanter och metriska omvandlingar visas i
tabellerna.
integer / bilangan bulat / soá nguyeân
•
•
Fysikaaliset vakiot ja metrimuunnokset näkyvät taulukoista.
Ç Ú‡·Îˈ‡ı ÔÓ͇Á‡Ì˚ ÙËÁ˘ÂÒÍË ÍÓÌÒÚ‡ÌÚ˚ Ë
ÏÂÚ˘ÂÒÍË ÔÂÓ·‡ÁÓ‚‡ÌËfl.
In Europe:
•
Fysiske konstanter og metriske omskrivninger vises i tabellen.
•
•
This equipment complies with the requirements of Directive 89/336/
EEC as amended by 93/68/EEC.
•
•
Dieses Gerät entspricht den Anforderungen der EG-Richtlinie 89/336/
EWG mit Änderung 93/68/EWG.
Pemalar Fizik dan Pertukaran Metrik ditunjukkan di dalam
jadual.
Konstanta Fisika dan Konversi Metrik diperlihatkan di dalam
tabel.
Caùc Haèng soá Vaät lyù vaø caùc Pheùp bieán ñoåi Heä meùt ñöôïc theå
hieän trong caùc baûng.
Ce matériel répond aux exigences contenues dans la directive 89/336/
CEE modifiée par la directive 93/68/CEE.
•
•
Dit apparaat voldoet aan de eisen van de richtlijn 89/336/EEG,
gewijzigd door 93/68/EEG.
Dette udstyr overholder kravene i direktiv nr. 89/336/EEC med tillæg
nr. 93/68/EEC.
PHYSICAL CONSTANTS
ß 01 — 52
Quest’ apparecchio è conforme ai requisiti della direttiva 89/336/EEC
come emendata dalla direttiva 93/68/EEC.
No. SYMBOL UNIT
No. SYMBOL UNIT
No. SYMBOL UNIT
01 - c, c0 m s–1
19 - µΒ
J T–1
J T–1
J T–1
J T–1
J T–1
J T–1
m
37 - eV
38 - t
J
ꢀ ꢁꢂꢃꢄꢅꢆꢇꢅꢄꢇꢈ ꢄꢉꢅꢊ ꢄꢋꢅꢄꢌꢍꢃꢎꢏꢋꢁꢅꢄꢐ ꢇꢅꢐꢑ ꢄꢌꢄꢐꢅꢊꢇꢁꢐꢑ ꢅꢒꢋ
ꢍꢓꢈꢂꢐꢔꢋ ꢅꢈꢑ ꢕꢉꢎꢒꢌꢄꢖꢃꢊꢑ ꢕꢋꢒꢇꢈꢑ 89/336/ꢕꢗꢘ, ꢙꢌꢒꢑ ꢍ
ꢃꢄꢋꢍꢋꢐꢇꢚꢙꢑ ꢄꢉꢅꢙꢑ ꢇꢉꢚꢌꢛꢈꢎꢔꢜꢈꢃꢁ ꢄꢌꢙ ꢅꢈꢋ ꢍꢓꢈꢂꢏꢄ 93/68/ꢕꢗꢘ.
02 - G
03 - gn
04 - me
05 - mp
06 - mn
m3 kg–1 s–2 20 - µe
K
m
m
m s–2
kg
21 - µΝ
22 - µp
23 - µn
24 - µµ
25 - λc
26 - λc, p
27 - σ
39 - AU
Este equipamento obedece às exigências da directiva 89/336/CEE na
sua versão corrigida pela directiva 93/68/CEE.
40 - pc
41 - M(12C) kg mol–1
kg
Este aparato satisface las exigencias de la Directiva 89/336/CEE
modificada por medio de la 93/68/CEE.
-
kg
42 - h
J s
J
07 - m
kg
43 - Eh
µ
Denna utrustning uppfyller kraven enligt riktlinjen 89/336/EEC så som
kompletteras av 93/68/EEC.
08 - lu
09 - e
kg
m
44 - G0
s
–1
C
W m–2 K–4 45 - α
Dette produktet oppfyller betingelsene i direktivet 89/336/EEC i
endringen 93/68/EEC.
10 - h
11 - k
J s
28 - NΑ, L mol–1
46 - mp/me
J K–1
N A–2
F m–1
m
29 - Vm
30 - R
31 - F
32 - RK
-
m3 mol–1
J mol–1 K–1 48 - λc, n
C mol–1
47 - Mu
kg mol–1
m
W m2
m K
Ω
Tämä laite täyttää direktiivin 89/336/EEC vaatimukset, jota on
muutettu direktiivillä 93/68/EEC.
12 - µ0
13 - ε0
14 - re
15 - α
16 - a0
17 - R
49 - c1
50 - c2
51 - Z0
52 -
чÌÌÓ ÛÒÚÓÈÒÚ‚Ó ÒÓÓÚ‚ÂÚÒÚ‚ÛÂÚ Ú·ӂ‡ÌËflÏ ‰ËÂÍÚË‚˚ 89/336/
EEC Ò Û˜ÂÚÓÏ ÔÓÔ‡‚ÓÍ 93/68/EEC.
Ez a készülék megfelel a 89/336/EGK sz. EK-irányelvben és annak 93/
68/EGK sz. módosításában foglalt követelményeknek.
Ohm
33 - e/me C kg–1
m
m–1
34 - h/2me m2 s–1
Pa
35 - γp
36 - KJ
s–1 T–1
Hz V–1
∞
Tento pfiístroj vyhovuje poÏadavkÛm smûrnice 89/336/EEC v platném
znûní 93/68/EEC.
18 - Φ0
Wb
METRIC CONVERSIONS
x @¥ 1 — 44
Nur für Deutschland/For Germany only:
No.
1
UNIT
No.
UNIT
No.
31
32
33
34
35
36
37
UNIT
Umweltschutz
Das Gerät wird durch eine Batterie mit Strom versorgt.
Um die Batterie sicher und umweltschonend zu entsorgen,
beachten Sie bitte folgende Punkte:
in→cm
cm→in
ft→m
16 kg→lb
17 °F→°C
18 °C→°F
J→calIT
calIT→J
hp→W
W→hp
ps→W
W→ps
kgf/cm2→Pa
Pa→kgf/cm2
atm→Pa
Pa→atm
mmHg→Pa
Pa→mmHg
kgf·m→J
J→kgf·m
2
3
•
Bringen Sie die leere Batterie zu Ihrer örtlichen Mülldeponie,
zum Händler oder zum Kundenservice-Zentrum zur
Wiederverwertung.
4
m→ft
yd→m
m→yd
mile→km
km→mile
n mile→m
m→n mile
acre→m2
m2→acre
oz→g
19 gal (US)→l
20 l→gal (US)
21 gal (UK)→l
22 l→gal (UK)
23 fl oz (US)→ml 38
24 ml→fl oz (US) 39
25 fl oz (UK)→ml 40
26 ml→fl oz (UK) 41
27 J→cal
28 cal→J
29
30
5
•
Werfen Sie die leere Batterie niemals ins Feuer, ins Wasser
oder in den Hausmüll.
6
7
8
Seulement pour la France/For France only:
9
Protection de l’environnement
L’appareil est alimenté par pile. Afin de protéger
l’environnement, nous vous recommandons:
10
11
12
13
14
15
•
d’apporter la pile usagée ou à votre revendeur ou au service
après-vente, pour recyclage.
42
43
44
•
de ne pas jeter la pile usagée dans une source de chaleur,
dans l’eau ou dans un vide-ordures.
g→oz
lb→kg
J→cal15
cal15→J
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