A.2.2: Section 2.2 Answers
- Page ID
- 43752
1. \(y=2\pm\sqrt{2(x^{3}+x^{2}+x+c)}\)
2. \(\ln (|\sin y|)=\cos x+c; \quad y ≡ k\pi,\quad k=\text{integer}\)
3. \(y=\frac{c}{x-c}\quad y≡-1\)
4. \(\frac{(\ln y)^{2}}{2}=-\frac{x^{3}}{3}+c\)
5. \(y^{3}+3\sin y+\ln |y|+\ln (1+x^{2})+\tan ^{-1}x=c;\quad y≡0\)
6. \(y=\pm\left( 1+\left(\frac{x}{1+cx}\right) ^{2}\right) ^{1/2} ;\quad y≡\pm 1\)
7. \(y=\tan \left(\frac{x^{3}}{3}+c \right)\)
8. \(y=\frac{c}{\sqrt{1+x^{2}}}\)
9. \(y=\frac{2-ce^{(x-1)^{2}/2}}{1-ce^{(x-1)^{2}/2}};\quad y≡1\)
10. \(y=1+(3x^{2}+9x+c)^{1/3}\)
11. \(y=2+\sqrt{\frac{2}{3}x^{3}+3x^{2}+4x-\frac{11}{3}}\)
12. \(y=\frac{e^{-(x^{2}-4)/2}}{2-e^{-(x^{2}-4)/2}}\)
13. \(y^{3}+2y^{2}+x^{2}+\sin x=3\)
14. \((y+1)(y-1)^{-3}(y-2)^{2}=-256(x+1)^{-6}\)
15. \(y=-1+3e^{-x^{2}}\)
16. \(y=\frac{1}{\sqrt{2e^{-2x^{2}}-1}}\)
17. \(y≡-1;\quad (-\infty ,\infty )\)
18. \(y=\frac{4-e^{-x^{2}}}{2-e^{-x^{2}}}; \quad (-\infty ,\infty )\)
19. \(y=\frac{-1+\sqrt{4x^{2}-15}}{2}; \quad \left(\frac{\sqrt{15}}{2},\infty \right)\)
20. \(y=\frac{2}{1+e^{-2x}}\quad (-\infty ,\infty )\)
21. \(y=-\sqrt{25-x^{2}};\quad (-5,5)\)
22. \(y≡2,\quad (-\infty ,\infty )\)
23. \(y=3\left(\frac{x+1}{2x-4} \right)^{1/3};\quad (-\infty ,2)\)
24. \(y=\frac{x+c}{1-cx}\)
25. \(y=-x\cos c+\sqrt{1-x^{2}}\sin c;\quad y≡1; \:y≡-1\)
26. \(y=-x+3\pi /2\)
28. \(P=\frac{P_{0}}{\alpha P_{0}+(1-\alpha P_{0})e^{-at}};\lim_{t\to\infty }P(t)=1/\alpha \)
29. \(I=\frac{SI_{0}}{I_{0}+(S-I_{0})e^{-rSt}}\)
30. \(\text{If }q=rS\text{ then }I=\frac{I_{0}}{1+rI_{0}t}\text{ and }\lim_{t\to\infty }I(t)=0.\text{ If }q\neq Rs\text{, then }I=\frac{\alpha I_{0}}{I_{0}+(\alpha -I_{0})e^{-r\alpha t}}.\text{ If } q<rs\text{, then }\lim_{t\to\infty}I(t)=\alpha =S-\frac{q}{r}\text{ if }q>rS\text{, then }\lim_{t\to\infty}I(t)=0\)
34. \(f=ap,\quad \text{where }a=\text{constant}\)
35. \(y=e^{-x}(-1\pm\sqrt{2x^{2}+c})\)
36. \(y=x^{2}(-1+\sqrt{x^{2}+c})\)
37. \(y=e^{x}(-1+(3xe^{x}+c)^{1/3})\)
38. \(y=e^{2x}(1\pm\sqrt{c-x^{2}})\)
39.
- \(y_{1}=1/x;\quad g(x)=h(x)\)
- \(y_{1}=x;\quad g(x)=h(x)/x^{2}\)
- \(y_{1}=e^{-x};\quad g(x)=e^{x}h(x)\)
- \(y_{1}=x^{-r};\quad g(x)=x^{r-1}h(x)\)
- \(y_{1}=1/v(x);\quad g(x)=v(x)h(x)\)