Trigonometrie Beispiele

sin (7 x)

$\sin (7 x)$

Schritt 1

Eine gute Methode

sin (7 x)

$\sin (7 x)$ zu entwickeln, ist die Anwendung des Satzes von de Moivre

(r {(cos (x) + i \cdot sin (x))}^{n} = r^{n} (cos (n x) + i \cdot sin (n x)))

$(r {(\cos (x) + i \cdot \sin (x))}^{n} = r^{n} (\cos (n x) + i \cdot \sin (n x)))$ . Wenn

r = 1

$r = 1$ ,

cos (n x) + i \cdot sin (n x) = {(cos (x) + i \cdot sin (x))}^{n}

$\cos (n x) + i \cdot \sin (n x) = {(\cos (x) + i \cdot \sin (x))}^{n}$ .

cos (n x) + i \cdot sin (n x) = {(cos (x) + i \cdot sin (x))}^{n}

$\cos (n x) + i \cdot \sin (n x) = {(\cos (x) + i \cdot \sin (x))}^{n}$

Schritt 2

Multipliziere die rechte Seite der Gleichung

cos (n x) + i \cdot sin (n x) = {(cos (x) + i \cdot sin (x))}^{n}

$\cos (n x) + i \cdot \sin (n x) = {(\cos (x) + i \cdot \sin (x))}^{n}$ durch Anwenden des binomischen Lehrsatzes aus.

Multipliziere aus:

{(cos (x) + i \cdot sin (x))}^{7}

${(\cos (x) + i \cdot \sin (x))}^{7}$

Schritt 3

Wende den binomischen Lehrsatz an.

{cos}^{7} (x) + 7 {cos}^{6} (x) (i sin (x)) + 21 {cos}^{5} (x) {(i sin (x))}^{2} + 35 {cos}^{4} (x) {(i sin (x))}^{3} + 35 {cos}^{3} (x) {(i sin (x))}^{4} + 21 {cos}^{2} (x) {(i sin (x))}^{5} + 7 cos (x) {(i sin (x))}^{6} + {(i sin (x))}^{7}

$\cos^{7} (x) + 7 \cos^{6} (x) (i \sin (x)) + 21 \cos^{5} (x) {(i \sin (x))}^{2} + 35 \cos^{4} (x) {(i \sin (x))}^{3} + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4

Vereinfache Terme.

Tippen, um mehr Schritte zu sehen ...

Schritt 4.1

Vereinfache jeden Term.

Tippen, um mehr Schritte zu sehen ...

Schritt 4.1.1

Wende die Produktregel auf

i sin (x)

$i \sin (x)$ an.

{cos}^{7} (x) + 7 {cos}^{6} (x) i sin (x) + 21 {cos}^{5} (x) (i^{2} {sin}^{2} (x)) + 35 {cos}^{4} (x) {(i sin (x))}^{3} + 35 {cos}^{3} (x) {(i sin (x))}^{4} + 21 {cos}^{2} (x) {(i sin (x))}^{5} + 7 cos (x) {(i sin (x))}^{6} + {(i sin (x))}^{7}

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) + 21 \cos^{5} (x) (i^{2} \sin^{2} (x)) + 35 \cos^{4} (x) {(i \sin (x))}^{3} + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.2

Schreibe neu unter Anwendung des Kommutativgesetzes der Multiplikation.

{cos}^{7} (x) + 7 {cos}^{6} (x) i sin (x) + 21 \cdot i^{2} {cos}^{5} (x) {sin}^{2} (x) + 35 {cos}^{4} (x) {(i sin (x))}^{3} + 35 {cos}^{3} (x) {(i sin (x))}^{4} + 21 {cos}^{2} (x) {(i sin (x))}^{5} + 7 cos (x) {(i sin (x))}^{6} + {(i sin (x))}^{7}

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) + 21 \cdot i^{2} \cos^{5} (x) \sin^{2} (x) + 35 \cos^{4} (x) {(i \sin (x))}^{3} + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.3

Schreibe

i^{2}

$i^{2}$ als

- 1

$- 1$ um.

{cos}^{7} (x) + 7 {cos}^{6} (x) i sin (x) + 21 \cdot - 1 {cos}^{5} (x) {sin}^{2} (x) + 35 {cos}^{4} (x) {(i sin (x))}^{3} + 35 {cos}^{3} (x) {(i sin (x))}^{4} + 21 {cos}^{2} (x) {(i sin (x))}^{5} + 7 cos (x) {(i sin (x))}^{6} + {(i sin (x))}^{7}

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) + 21 \cdot - 1 \cos^{5} (x) \sin^{2} (x) + 35 \cos^{4} (x) {(i \sin (x))}^{3} + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.4

Mutltipliziere

21

$21$ mit

- 1

$- 1$ .

{cos}^{7} (x) + 7 {cos}^{6} (x) i sin (x) - 21 {cos}^{5} (x) {sin}^{2} (x) + 35 {cos}^{4} (x) {(i sin (x))}^{3} + 35 {cos}^{3} (x) {(i sin (x))}^{4} + 21 {cos}^{2} (x) {(i sin (x))}^{5} + 7 cos (x) {(i sin (x))}^{6} + {(i sin (x))}^{7}

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) + 35 \cos^{4} (x) {(i \sin (x))}^{3} + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.5

Wende die Produktregel auf

$i \sin (x)$ an.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) + 35 \cos^{4} (x) (i^{3} \sin^{3} (x)) + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.6

Schreibe neu unter Anwendung des Kommutativgesetzes der Multiplikation.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) + 35 \cdot i^{3} \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.7

Faktorisiere

$i^{2}$ aus.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) + 35 \cdot (i^{2} \cdot i) \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.8

Schreibe

$i^{2}$ als

$- 1$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) + 35 \cdot (- 1 \cdot i) \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.9

Schreibe

$- 1 i$ als

$- i$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) + 35 \cdot (- i) \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.10

Mutltipliziere

$- 1$ mit

$35$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) {(i \sin (x))}^{4} + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.11

Wende die Produktregel auf

$i \sin (x)$ an.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) (i^{4} \sin^{4} (x)) + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.12

Schreibe neu unter Anwendung des Kommutativgesetzes der Multiplikation.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cdot i^{4} \cos^{3} (x) \sin^{4} (x) + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.13

Schreibe

$i^{4}$ als

$1$ um.

Tippen, um mehr Schritte zu sehen ...

Schritt 4.1.13.1

Schreibe

$i^{4}$ als

${(i^{2})}^{2}$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cdot {(i^{2})}^{2} \cos^{3} (x) \sin^{4} (x) + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.13.2

Schreibe

$i^{2}$ als

$- 1$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cdot {(- 1)}^{2} \cos^{3} (x) \sin^{4} (x) + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.13.3

Potenziere

$- 1$ mit

$2$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cdot 1 \cos^{3} (x) \sin^{4} (x) + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.14

Mutltipliziere

$35$ mit

$1$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cos^{2} (x) {(i \sin (x))}^{5} + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.15

Wende die Produktregel auf

$i \sin (x)$ an.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cos^{2} (x) (i^{5} \sin^{5} (x)) + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.16

Schreibe neu unter Anwendung des Kommutativgesetzes der Multiplikation.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cdot i^{5} \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.17

Faktorisiere

$i^{4}$ aus.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cdot (i^{4} i) \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.18

Schreibe

$i^{4}$ als

$1$ um.

Tippen, um mehr Schritte zu sehen ...

Schritt 4.1.18.1

Schreibe

$i^{4}$ als

${(i^{2})}^{2}$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cdot ({(i^{2})}^{2} i) \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.18.2

Schreibe

$i^{2}$ als

$- 1$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cdot ({(- 1)}^{2} i) \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.18.3

Potenziere

$- 1$ mit

$2$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cdot (1 i) \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.19

Mutltipliziere

$i$ mit

$1$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 \cdot i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) {(i \sin (x))}^{6} + {(i \sin (x))}^{7}$

Schritt 4.1.20

Wende die Produktregel auf

$i \sin (x)$ an.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) (i^{6} \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.21

Faktorisiere

$i^{4}$ aus.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) (i^{4} i^{2} \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.22

Schreibe

$i^{4}$ als

$1$ um.

Tippen, um mehr Schritte zu sehen ...

Schritt 4.1.22.1

Schreibe

$i^{4}$ als

${(i^{2})}^{2}$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) ({(i^{2})}^{2} i^{2} \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.22.2

Schreibe

$i^{2}$ als

$- 1$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) ({(- 1)}^{2} i^{2} \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.22.3

Potenziere

$- 1$ mit

$2$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) (1 i^{2} \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.23

Mutltipliziere

$i^{2}$ mit

$1$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) (i^{2} \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.24

Schreibe

$i^{2}$ als

$- 1$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) (- 1 \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.25

Schreibe

$- 1 \sin^{6} (x)$ als

$- \sin^{6} (x)$ um.

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) + 7 \cos (x) (- \sin^{6} (x)) + {(i \sin (x))}^{7}$

Schritt 4.1.26

Mutltipliziere

$- 1$ mit

$7$ .

$\cos^{7} (x) + 7 \cos^{6} (x) i \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) - 7 \cos (x) \sin^{6} (x) + {(i \sin (x))}^{7}$

Schritt 4.1.27

Wende die Produktregel auf

$i \sin (x)$ an.

Schritt 4.1.28

Schreibe

$i^{7}$ als

$i^{4} (i^{2} \cdot i)$ um.

Tippen, um mehr Schritte zu sehen ...

Schritt 4.1.28.1

Faktorisiere

$i^{4}$ aus.

Schritt 4.1.28.2

Faktorisiere

$i^{2}$ aus.

Schritt 4.1.29

Schreibe

$i^{4}$ als

$1$ um.

Tippen, um mehr Schritte zu sehen ...

Schritt 4.1.29.1

Schreibe

$i^{4}$ als

${(i^{2})}^{2}$ um.

Schritt 4.1.29.2

Schreibe

$i^{2}$ als

$- 1$ um.

Schritt 4.1.29.3

Potenziere

$- 1$ mit

$2$ .

Schritt 4.1.30

Mutltipliziere

$i^{2} \cdot i$ mit

$1$ .

Schritt 4.1.31

Schreibe

$i^{2}$ als

$- 1$ um.

Schritt 4.1.32

Schreibe

$- 1 i$ als

$- i$ um.

Schritt 4.2

Stelle die Faktoren in

$\cos^{7} (x) + 7 i \cos^{6} (x) \sin (x) - 21 \cos^{5} (x) \sin^{2} (x) - 35 i \cos^{4} (x) \sin^{3} (x) + 35 \cos^{3} (x) \sin^{4} (x) + 21 i \cos^{2} (x) \sin^{5} (x) - 7 \cos (x) \sin^{6} (x) - i \sin^{7} (x)$

Schritt 5

Ziehe die Ausdrücke mit dem imaginären Teil heraus, welche gleich

$\sin (7 x)$ sind. Entferne die imaginäre Zahl

$i$ .

$\sin (7 x) = 7 \cos^{6} (x) \sin (x) - 35 \cos^{4} (x) \sin^{3} (x) + 21 \cos^{2} (x) \sin^{5} (x) - \sin^{7} (x)$