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Withdraw money from the app to the wallet of one of the world’s most popular payment systems. hard logarithm problems with solutions pdf
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Check domain: all real OK
You don’t need to invest anything, in fact you will be rewarded with $0.5 for your registration. So (x>0), (x\neq 1)
Check domain: all real OK. (x=0, \sqrt{6}, -\sqrt{6}). Solution 3 Domain: (x>0), (x\neq 1), (2x+3>0 \Rightarrow x>-1.5), (x+1>0) and (x+1\neq 1 \Rightarrow x> -1, x\neq 0), plus (x+2>0) (automatic). So (x>0), (x\neq 1).
Answer: No real solution. Domain: (x>0, x\neq 1, 2x>0, 2x\neq 1, 4x>0, 4x\neq 1) → (x>0, x\neq 1, x\neq 0.5, x\neq 0.25).
Challenging Exercises for Advanced High School & Early College Students
(0 < \log_2 A < 1 \Rightarrow 1 < A < 2 \Rightarrow 1 < x^2-5x+7 < 2).
Left: (x^2-5x+6>0 \Rightarrow x<2) or (x>3) (same as domain). Right: (x^2-5x+5<0). Roots: (\frac{5\pm\sqrt{5}}{2} \approx 1.38, 3.62). So ( \frac{5-\sqrt{5}}{2} < x < \frac{5+\sqrt{5}}{2}).
So (\ln x = \pm \ln(2^{\sqrt{2}})) ⇒ (x = 2^{\sqrt{2}}) or (x = 2^{-\sqrt{2}}).
Check domain: both >0, ≠1, ≠0.5, ≠0.25? (2^{\sqrt{2}} \approx 2^{1.414}\approx 2.665) fine. (2^{-\sqrt{2}} \approx 0.375) — not 0.5 or 0.25, fine.
Title: Hard Logarithm Problems with Detailed Solutions
Let (a = \ln x). Then (\ln(2x) = a + \ln 2), (\ln(4x) = a + 2\ln 2).
Change base: (\log_{x}(2x+3) = \frac{\ln(2x+3)}{\ln x}), (\log_{x+1}(x+2) = \frac{\ln(x+2)}{\ln(x+1)}).
Try (x=2) gave 4.07, (x=4): (\log_4(11)=1.73), (\log_5(6)=1.113), sum=2.843. (x) smaller: (x=1.5): (\log_{1.5}(6)\approx 4.419), (\log_{2.5}(3.5)\approx 1.209), sum=5.628. So sum decreases? Wait from 5.6 at 1.5 to 2.84 at 4 — crosses 2 somewhere? At (x=1.5) sum 5.6, (x=4) sum 2.84, (x=8): (\log_8(19)\approx 1.418), (\log_9(10)\approx 1.047), sum=2.465. So decreasing but above 2, min? As (x\to\infty), both terms →1, sum→2 from above. So sum>2 always? Then no solution? Check (x\to 1^+): first term →∞, second term → finite, sum→∞. So minimum near large x? As x large, approx: (\log_x(2x)=\log_x 2 + 1), (\log_{x+1}(x+2)\approx 1), sum ≈ 2 + small positive. So min sum>2, so .
Check domain: all real OK. (x=0, \sqrt{6}, -\sqrt{6}). Solution 3 Domain: (x>0), (x\neq 1), (2x+3>0 \Rightarrow x>-1.5), (x+1>0) and (x+1\neq 1 \Rightarrow x> -1, x\neq 0), plus (x+2>0) (automatic). So (x>0), (x\neq 1).
Answer: No real solution. Domain: (x>0, x\neq 1, 2x>0, 2x\neq 1, 4x>0, 4x\neq 1) → (x>0, x\neq 1, x\neq 0.5, x\neq 0.25).
Challenging Exercises for Advanced High School & Early College Students
(0 < \log_2 A < 1 \Rightarrow 1 < A < 2 \Rightarrow 1 < x^2-5x+7 < 2).
Left: (x^2-5x+6>0 \Rightarrow x<2) or (x>3) (same as domain). Right: (x^2-5x+5<0). Roots: (\frac{5\pm\sqrt{5}}{2} \approx 1.38, 3.62). So ( \frac{5-\sqrt{5}}{2} < x < \frac{5+\sqrt{5}}{2}).
So (\ln x = \pm \ln(2^{\sqrt{2}})) ⇒ (x = 2^{\sqrt{2}}) or (x = 2^{-\sqrt{2}}).
Check domain: both >0, ≠1, ≠0.5, ≠0.25? (2^{\sqrt{2}} \approx 2^{1.414}\approx 2.665) fine. (2^{-\sqrt{2}} \approx 0.375) — not 0.5 or 0.25, fine.
Title: Hard Logarithm Problems with Detailed Solutions
Let (a = \ln x). Then (\ln(2x) = a + \ln 2), (\ln(4x) = a + 2\ln 2).
Change base: (\log_{x}(2x+3) = \frac{\ln(2x+3)}{\ln x}), (\log_{x+1}(x+2) = \frac{\ln(x+2)}{\ln(x+1)}).
Try (x=2) gave 4.07, (x=4): (\log_4(11)=1.73), (\log_5(6)=1.113), sum=2.843. (x) smaller: (x=1.5): (\log_{1.5}(6)\approx 4.419), (\log_{2.5}(3.5)\approx 1.209), sum=5.628. So sum decreases? Wait from 5.6 at 1.5 to 2.84 at 4 — crosses 2 somewhere? At (x=1.5) sum 5.6, (x=4) sum 2.84, (x=8): (\log_8(19)\approx 1.418), (\log_9(10)\approx 1.047), sum=2.465. So decreasing but above 2, min? As (x\to\infty), both terms →1, sum→2 from above. So sum>2 always? Then no solution? Check (x\to 1^+): first term →∞, second term → finite, sum→∞. So minimum near large x? As x large, approx: (\log_x(2x)=\log_x 2 + 1), (\log_{x+1}(x+2)\approx 1), sum ≈ 2 + small positive. So min sum>2, so .
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