Sharp EL-506 Manual

0 (0)

EL-506V

EL-546V

Operation Examples

Bedienungsbeispiele

Exemples d’opérations

Ejemplos de operación

Esempi di calcolo

Rekenvoorbeelden

Exemplos de Operação

Operationsexempel

Käyttöesimerkkejä

PRINTED IN CHINA/IMPRIMÉ EN CHINE/IMPRESO EN CHINA 00LUP(TINSZ0442EHZZ)

(1) []

1	3(5+2)=			ª3 (5 +2 )=			21.
2	3× 5+2=			3 *5 +2 =			17.
3	3× 5+3× 2=			3 5 +3 2 =			21.
→	1			@[
→	2			]
→	3			]
→	2			[

(2) +-*/()±E

45+285÷3=				ª45		+285 /3 =	140.

18+6			=	(18		+6 )/
15–8				(15		-8 =	3.428571429

42×		(–5)+120=		42	*	5 ±+120 =	–90.

				1 (±5) 1
(5× 103)÷(4× 10–3)= 5 E3 /4 E3 ±= 1250000.

(3)

34+57=				34	+	57 =	91.
45+57=				45		=	102.

68×		25=		68	*	25 =	1700.
68×		40=				40 =	2720.

(4) sutSUT°(sinh, sinh–1, cosh, cosh–1, tanh, tanh–1) VGIle ¡•L⁄™$#!q Q%

sin60[°]=							ªs60 =	0.866025403
			π				@Gu(@V/
cos–[rad]=
		4					4 )=	0.707106781


tan–11=[g]							@G@T1 =	50.
							@G

(cosh 1.5 +							ª(°°°1*1 1.5 +
sinh 1.5)2 =
							°°11.5 )L=20.08553692
							*1 cosh

tanh–15– =							°°°°2(5 /
		7					7 )=	0.895879734

ln 20 =							I20 =	2.995732274

log 50 =							l50 =	1.698970004

e3 =							@e3 =	20.08553692
101.7 =							@¡1.7 =	50.11872336
1		1					6 @•+7 @•=0.309523809
– + – =
6		7

8–2 – 34× 52 =							8 ™2 ±-3 ™4 *
							5 L=	–2024.984375

		1					12 ™3 ™4 @•= 6.447419591
				–
(123)4 =

√			–4√			=	@⁄49 -4 @$81 = 4.
	49				81
3√							@#27 =	3.
		27=
4! =							4 @!=	24.

10P3 =							10 @q3 =	720.
5C2 =							5 @Q2 =	10.
500× 25%=							500 *25 @%	125.

120÷400=?%							120 /400 @%	30.

500+(500×						25%)=	500 +25 @%	625.

400–(400×						30%)=	400 -30 @%	280.

	θ	= sin–1 x, θ		= tan–1 x		θ = cos–1 x
DEG		–90 ≤	θ	≤	90	0 ≤	θ	≤	180

RAD		π	θ	≤	π	0 ≤		θ	≤ π
RAD		– — ≤	θ	≤	—	0 ≤		θ	≤ π
		2			2
GRAD		–100 ≤	θ	≤	100	0 ≤	θ	≤	200

(5) Åè

d/dx (x4 – 0.5x3 + 6x2) ª@KX™4 -0.5 @K

	x=2	X™3	+6 @KXL
	dx=0.0002	@Å2	®®	50.
	x=3	®3 ®0.001 ®		130.500003
	dx=0.001
∫28 (x2 – 5)dx @KXL-5
n=100		è2 ®8 ®®		138.
n=10		®®®10 ®		138.

(6) g

90°→ [rad]	ª90 @g	1.570796327
→ [g]	@g	100.
→ [°]	@g	90.

sin–10.8 = [°]	@S0.8 =	53.13010235
→ [rad]	@g	0.927295218
→ [g]	@g	59.03344706
→ [°]	@g	53.13010235

(7) RO;:?≥Ω
					F2

					ª8 *2 OM	16.
24÷(8× 2)=					24 /RM=	1.5

(8× 2)× 5=					RM*5 =	80.

					ªOM	0.
$150× 3:M1					150 *3 ;	450.
+)$250:M2 =M1+250					250 ;	250.
–)M2× 5%					RM*5 @%	35.
	M				@:RM	665.

$1= ¥140					140 OY	140.
¥33,775=$?					33775 /RY=	241.25
$2,750=¥?					2750 *RY=	385000.

[EL-506V]
π r2 F1					@V@KY
					LO≥	F1
		4			3 OY	3.
3					3 OY	3.
3				V = ?	R≥*4 /3 =37.69911184
				V = ?	R≥*4 /3 =37.69911184

	24		= 2.4...(A)		24 /(4 +6 )=	2.4
4+6			= 2.4...(A)		24 /(4 +6 )=	2.4
4+6					3 *@?+60 /
3× (A)+60÷(A)=					3 *@?+60 /
3× (A)+60÷(A)=					@?=	32.2

(8)

6+4=ANS			ª6	+4 =	10.
ANS+5			+5	=	15.

44+37=ANS			44 +37 =		81.
√		=	@⁄=		9.
	ANS

(9) \|

1 4			b	ª3 \1 \2 +
3– + – = [a–]
2 3			c	4 \3 =	4 l5 l6 *
2 3				4 \3 =	4 l5 l6 *
→ [a.xxx]				\	4.833333333
→ [d/c]				@\|	29 l6
2
10	3	=		@¡2 \3 =	4.641588834

			2	1.25 +2 \5 =	1.65
1.25 + – = [a.xxx]				1.25 +2 \5 =	1.65
		b	5	\	1 l13 l20
→ [a–]				\	1 l13 l20
		c
1.65				ª1.65 =	1.65
		b		\	1 l13 l20
→ [a–]				\	1 l13 l20
		c
→ [d/c]				@\|	33 l20
→ [a.xxx]				\	1.65

* 4 l5 l6=4—

(10)комнгв†да

DEC(25)→ BIN		ª@í25 @ê 11001.b
HEX(1AC)		@ì1AC
→	BIN	@ê		110101100.b
→	OCT	@î		654.0
→	DEC	@í		428.

BIN		@ê(1010 -100 )
(1010–100)× 11 = *11 =				10010.b
BIN(111)→ NEG ã111 =				1111111001.b
HEX(1FF)+		@ì1FF @î+
OCT(512)=		512 =		1511.0
HEX(?)		@ì		349.H
2FEC–		ªOM@ì2FEC -
2C9E=(A)		2C9E ;		34E.H
+)2000–		2000 -
1901=(B)		1901 ;		6FF.H
(C)		RM		A4d.H
1011 AND		ª@ê1011 †
101 = (BIN)		101 =		1.b
5A OR C3 = (HEX) @ì			5A äC3 =	db.H
NOT 10110 =		@êâ10110 =		1111101001.b
(BIN)

24 XOR 4 = (OCT) @î			24 à4 =	20.0
B3 XNOR		@ìB3 á		FFFFFFFF61.H
2D = (HEX)		2D =
→	DEC	@í		–159.

(11) o_

12°39’18”05	ª12 o39 o18 o5
→ [10]	@_	12.65501389

123.678	123.678 @_	123°40’40.80

→[60]

3h30m45s +	3 o30 o45 +
6h45m36s = [60]	6 o45 o36 =	10°16’21.00

3h45m – 1.69h 3 o45 -1.69 =
= [60]	@_	2°03’36.00

sin62°12’24” = [10] s62 o12 o24 = 0.884635235

(12) °(→ rθ , → xy) ,≠

x = 6			r =		ª6 @,4 °1[r ] 7.211102551
y = 4	→		θ = [°]		@≠[θ ]	33.69006753
y = 4			θ = [°]		@≠[θ ]	33.69006753
					@≠[r ]	7.211102551

r = 14				x =	14 @,36 °2[x]	11.32623792
		→		y =	@≠[y]	8.228993532
θ = 36[°]				y =	@≠[x]	11.32623792
					@≠[x]	11.32623792

(13) ß

V0	= 15.3m/s		ª15.3 10 +2 @•
t = 10s			ß03 *10 L= 643.3325
	1	2
V t+ – gt = ?m
0	2

(14) ¥

125yd = ?m ª125 @¥5 = 114.3

(15) j

5÷9=ANS	ª@f@i1
ANS× 9=	5 /9 =	0.6
[FIX,TAB=1]	9 =1	5.0
	5 /9 =@j	0.6
	9 =2	5.4
	@f@f@f

*1 5.55555555555× 10–1× 9 *2 0.6× 9

(16) ≤®

@m0

f (x) = x3–3x2+2 @KX™3 -3 @K XL+2 ≤

x = –1		1 ±®	–2.
x = –0.5		≤0.5 ±®	1.125
√		@⁄(@KAL
	A2+B2
		+@KBL)≤
A = 2, B = 3		2 ®3 ®	3.605551275
A = 2, B = 5		≤®5 ®	5.385164807

(17) m(CPLX)

@m1

(12–6i) + (7+15i) – 12 -6 Ü+7 +15 Ü-

(11+4i) =	(11 +4 Ü)=[x] 8.
	@≠[y]	+ 5.i
	@≠[x]	8.

6× (7–9i) ×	6 (7 -9 Ü)
(–5+8i) =	(5 ±+8 Ü)=[x] 222.
	@≠[y]	+ 606.i

16× (sin30°+	16 *(s30 +Üu30 )
icos30°)÷(sin60°+	/(s60 +Üu60
icos60°)=	)=[x]	13.85640646
	@≠[y]	+ 8. i

y			°18 Ö70		+12 Ö25
A			°18 Ö70		+12 Ö25
A			=[r]			18.5408873
r1	r		=[r]			18.5408873
r1	r		@≠[θ	]		42.76427608
θ	r2	B	@≠[θ	]		42.76427608
θ 1	r2
θ 2		x
		x
r1 = 8, θ 1 = 70°
r2 = 12, θ 2 = 25°
↓
r = ?, θ		= ?°

(1 + i)		°21 +Ü=	1.
↓		°1[r]	1.414213562
r = ?, θ = ?°		@≠[θ ]	45.

		°2(2 -3 Ü)L
(2 – 3i)2 =		=[x]	–5.
		@≠[y]	– 12.i
1	=	(1 +Ü)@•=[x] 0.5
1 + i		@≠[y]	– 0.5i

(18) m(3-VLE)

			@m2
		x + y – z = 9	1 ®1 ®1 ±®9 ®
6x+6y – z =17			6 ®6 ®1 ±®17 ®
14x–7y+2z =42			14 ®7 ±®2 ®42
	x = ?		®[x]	3.238095238
	y = ?		®[y]	–1.638095238
	z = ?		®[z]	–7.4
	det(D) = ?		®[det(D)]	105.


		2x + 3y = 4	@c2 ®3 ®®4 ®
		5x + 6y = 7
		5x + 6y = 7	5 ®6 ®®7 ®
	x = ?		®®®®[x]	–1.
	y = ?		®[y]	2.
	det(D) = ?		®[det(D)]	–3.

(19) m(STAT0: SD) °(→ t, P(, Q(, R()

		DATA			0.
		DATA
	95			@m30
	80			95 k	1.
	80			80 k	2.
	75			k	3.
	75			75 &3 k	6.
	75			50 k	7.
	50
			x=	R~	75.71428571
		σ	x=	Rp	12.37179148
		Σ	x=	Rz	530.
		Σ x2 =		Rw	41200.
		sx=		R£	13.3630621
		sx2 =		L=	178.5714286
				°°°°°2*1 60 °
x = 60 → P(t) ?
x = 60 → P(t) ?				°°°°1)= 0.102012
t = –0.5 → R(t) ? °°°°°4
				0.5 ±)=	0.691463
				*1 P(

(20) m(STAT1: a+bx)

	x	y	@m31		0.
2		5	2 &5 k		1.
2		5	k		2.
12		24	12	&24 k	3.
21		40	21	&40 &3 k	6.
21		40	15	&25 k	7.
21		40	Ra		1.050261097
15		25	Rb		1.826044386
			Rr		0.995176343
			R£		8.541216597
			R¢		15.67223812
x=3 →		y’=?	3 @y		6.528394256
y=46 →		x’=?	46	@x	24.61590706

(21) m(STAT2: ··+cx2)

	x	y	@m32		0.
12		41	12	&41 k	1.
8		13	8 &13 k		2.
5		2	5 &2 k		3.
23		200	23	&200 k	4.
15		71	15	&71 k	5.
			Ra		5.357506761
			Rb		–3.120289663
			R©		0.503334057
x=10→ y’=?			10	@y	24.4880159
y=22→		x’=?	22	@x	9.63201409
			@≠		–3.432772026
			@≠		9.63201409

(22)

x =			Σ x	σ x =	Σ x2 – nx2
					n
			n
				Σ x = x1 + x2 + ··· +xn
sx =				Σ x2 = x12 + x22 + ··· +xn2
			Σ y	σ y =	Σ y2 – ny2
		=
	y
					n
			n

Σ xy = x1y1 + x2y2 + ··· +xnyn

sy =

Σ y = y1 + y2 + ··· +yn

Σ y2 = y12 + y22 + ··· +yn2

(23)

x – x t = ––––σ x

(24)

Function	Dynamic range
Funktion	zulässiger Bereich
Fonction	Plage dynamique
Función	Rango dinámico
Funzioni	Campi dinamici
Functie	Rekencapaciteit
Função	Limite dinâmico
Funktion	Definitionsområde
Funktio	Dynaaminen ala

DEG:

| x | < 1010

(tan x : | x | ≠

90 (2n–1))*

sin x, cos x,

RAD:

| x | < –––

× 10

tan x

180

(tan x : | x | ≠

– (2n–1))*

GRAD:

| x | < —–

× 10

100 (2n–1))*

(tan x : | x | ≠

sin–1x, cos–1x

| x | ≤ 1

tan–1x, 3¿x

| x | < 10100

In x, log x

10–99 ≤

x < 10100

•

y > 0:

–10100 < x log y < 100

•

y = 0:

0 < x < 10100

•

y < 0:

x = n (0 < | x | < 1: – = 2n–1, x ≠ 0)*,

–10100 < x log | y | < 100

•

y > 0:

100

–10

< – log y < 100 (x ≠ 0)

x¿y

•

y = 0:

0 < x < 10100

•

y < 0:

x = 2n–1

≠ 0)*,

(0 < | x | < 1 : – = n, x

100

–10 < – log | y | < 100

–10100 < x ≤ 230.2585092

10x

–10100 < x < 100

sinh x, cosh x,

| x | ≤ 230.2585092

tanh x

sinh–1 x

| x | < 1050

cosh–1 x

1 ≤

x < 1050

tanh–1 x

| x | < 1

| x | < 1050

¿x

0 ≤

x < 10100

x–1

| x | < 10100 (x ≠ 0)

0 ≤

n ≤

69*

nPr

0 ≤

r ≤

n ≤ 9999999999*

100

–—– < 10

(n-r)!

0 ≤

r ≤

n ≤ 9999999999*

nCr

0 ≤

r ≤

100

–—– < 10

(n-r)!

↔

DEG, D°M’S

0°00’00.01 ≤ | x | < 10000°

x, y →

r, θ

√

< 10100

x2 + y2

0 ≤

r < 10100

r, θ →

x, y

DEG:

| θ

| < 1010

RAD:

| θ

| < —–180

× 10

GRAD :

| θ

| < –– ×

DRG |

DEG→

RAD, GRAD→

DEG: | x | < 10100

RAD→

GRAD: | x | <

π– × 1098

(A+Bi)+(C+Di)

| A ± C | < 10100

(A+Bi)–(C+Di)

| B ± D | < 10100

(A+Bi)× (C+Di)

(AC – BD) < 10100

(AD + BC) < 10100

AC + BD

< 10100

C2 + D2

(A+Bi)÷(C+Di)

BC – AD

< 10100

C2 + D2

C2 + D2 ≠

→

DEC

| x | ≤ 9999999999

→

BIN

1000000000 ≤ x ≤

1111111111

→

OCT

0 ≤

x ≤

111111111

→

HEX

OCT

4000000000 ≤ x ≤

7777777777

AND

0 ≤

x ≤

3777777777

HEX

FDABF41C01 ≤ x ≤ FFFFFFFFFF

XOR

0 ≤

x ≤

2540BE3FF

XNOR

BIN

1000000000 ≤ x ≤

1111111111

0 ≤

x ≤

111111111

NOT

OCT

4000000000 ≤ x ≤

7777777777

0 ≤

x ≤

3777777777

HEX

FDABF41C01 ≤ x ≤ FFFFFFFFFF

0 ≤

x ≤

2540BE3FE

BIN

1000000001 ≤ x ≤

1111111111

0 ≤

x ≤

111111111

NEG

OCT

4000000001 ≤ x ≤

7777777777

0 ≤

x ≤

3777777777

HEX

FDABF41C01 ≤ x ≤ FFFFFFFFFF

0 ≤

x ≤

2540BE3FF

* (n, r: integer / ganze Zahlen / entier / entero / intero / geheel getal / inteiros / heltal / kokonaisluku / / / / / )

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.

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.

Quest’ apparecchio è conforme ai requisiti della direttiva 89/336/EEC come emendata dalla direttiva 93/68/EEC.

89/336/ , !"! ! " #$ ! 93/68/ .

Este equipamento obedece às exigências da directiva 89/336/CEE na sua versão corrigida pela directiva 93/68/CEE.

Este aparato satisface las exigencias de la Directiva 89/336/CEE modificada por medio de la 93/68/CEE.

Denna utrustning uppfyller kraven enligt riktlinjen 89/336/EEC så som kompletteras av 93/68/EEC.

Dette produktet oppfyller betingelsene i direktivet 89/336/EEC i endringen 93/68/EEC.

Tämä laite täyttää direktiivin 89/336/EEC vaatimukset, jota on muutettu direktiivillä 93/68/EEC.

PHYSICAL CONSTANTS

ß01 — 40

No. SYMBOL

UNIT

No. SYMBOL

UNIT

No. SYMBOL UNIT

- c

–1

- α

- Vm

–1

m·s

m ·mol

- G

–2

- a0

- R

–1

N·m·kg

J·mol ·K

- g

–2

- R∞

–1

- F

–1

m·s

C·mol

- me

- Φ

- RH

Ω

- mp

- µ

–1

- e/me

–1

J·T

C·kg

- mn

- µ

–1

- h/2me

–1

J·T

J·s·kg

- mµ

- µ

–1

- γ p

–1

J·T

·T

- u

- µ

–1

- 2e/h

–1

J·T

Hz·V

- e

- µ

–1

- eV

J·T

- h

J·s

24 -µ

–1

- t

J·T

- k

–1

- λ

- AU

J·K

- µ 0

–1

- λ

- pc

H·m

- ε 0

–1

- σ

–2

–4

F·m

W·m ·K

- re

- Ν

mol–1

METRIC CONVERSIONS

x @¥1 — 44

No.

UNIT

No.

UNIT

No.

UNIT

in→

kg→

J→ calIT

cm→

°F→

°C

calIT→ J

ft→ m

°C→

°F

hp→

m→

gal (US)→ l

W→

yd→

l→

gal (US)

ps→

m→

gal (UK)→ l

W→

mile→ km

l→

gal (UK)

kgf/cm2→

km→

mile

fl oz (US)→

Pa→

kgf/cm2

n mile→

ml→

fl oz (US)

atm→

m→

n mile

fl oz (UK)→

Pa→

atm

acre→

ml→

fl oz (UK)

mmHg→ Pa

m2→

acre

J→

cal

Pa→

mmHg

oz→

cal→

kgf·m→ J

g→ oz

J→

cal15

J→ kgf·m

lb→

cal15→

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