Tam giác ABC có \(b+c=2a\). Chứng minh rằng :
a) \(2\sin A=\sin B+\sin C\)
b) \(\dfrac{2}{h_a}=\dfrac{1}{h_b}+\dfrac{1}{h_c}\)
Cho tam giác ABC. Chứng minh rằng
\(\dfrac{h_b}{h_a^2}+\dfrac{h_c}{h_b^2}+\dfrac{h_a}{h_c^2}>\dfrac{1}{r}\)
\(\dfrac{h_b}{h_a^2}+\dfrac{h_c}{h_b^2}+\dfrac{h_a}{h_c^2}=\dfrac{\dfrac{2S_{ABC}}{b}}{\dfrac{4S_{ABC}^2}{a^2}}+\dfrac{\dfrac{2S_{ABC}}{c}}{\dfrac{4S^2_{ABC}}{b^2}}+\dfrac{\dfrac{2S_{ABC}}{a}}{\dfrac{4S_{ABC}^2}{c^2}}\)
\(=\dfrac{a^2}{2bS_{ABC}}+\dfrac{b^2}{2cS_{ABC}}+\dfrac{c^2}{2aS_{ABC}}\)
\(=\dfrac{1}{2S_{ABC}}\left(\dfrac{a^2}{b}+\dfrac{b^2}{c}+\dfrac{c^2}{a}\right)\)
\(\ge\dfrac{1}{2.\dfrac{a+b+c}{2}r}.\dfrac{\left(a+b+c\right)^2}{a+b+c}=\dfrac{1}{r}\)
Hình như có dấu = chứ nhỉ
Đẳng thức xảy ra khi tam giác ABC đều
Cho tam giác ABC. Chứng minh rằng:
a) \(S_{\Delta ABC}=\dfrac{1}{2}\sqrt{AB^2.AC^2-\left(\overrightarrow{AB}.\overrightarrow{AC}\right)^2}\)
b) \(b+c=2a\Leftrightarrow\dfrac{2}{h_a}=\dfrac{1}{h_b}+\dfrac{1}{h_c}\)
c) Góc A vuông \(\Leftrightarrow m_b^2+m_c^2=5m_a^2\)
Cho tam giác ABC có b-c=\(\dfrac{a}{2}\)
a, SinA=2sinB-2sinC
b, \(\dfrac{1}{h_a}=\dfrac{1}{h_b}-\dfrac{1}{h_c}\)
\(a=2b-2c\Rightarrow sinA.2R=2sinB.2R-2sinC.2R\)
\(\Rightarrow sinA=2sinB-2sinC\)
\(ah_a=bh_b=ch_c\Rightarrow\left(2b-2c\right)h_a=bh_b=ch_c\)
\(\Rightarrow\left\{{}\begin{matrix}\dfrac{1}{h_a}=\dfrac{2b-2c}{b}.\dfrac{1}{h_b}\\\dfrac{1}{h_a}=\dfrac{2b-2c}{c}.\dfrac{1}{h_c}\end{matrix}\right.\)
\(\Rightarrow\dfrac{1}{h_a}=\dfrac{1}{h_b}-\dfrac{1}{h_c}+\left(\dfrac{b}{c.h_c}-\dfrac{c}{b.h_b}\right)\)
Câu này đề sai tiếp, biểu thức \(\dfrac{b}{c.h_c}-\dfrac{c}{b.h_b}\) kia không thể bằng 0
Cho ΔABC, chứng minh rằng:
\(\dfrac{1}{r}=\dfrac{1}{h_a}+\dfrac{1}{h_b}+\dfrac{1}{h_c}\)
với \(h_a,h_b,h_c\) là các đường cao cỏn bán kính đường tròn nội tiếp tam giác
Cho tam giác nhọn ABC , AB = c, BC = a , AC = b . Trong đó b - c = \(\frac{a}{k}\)( k > 1 ). Gọi \(h_a\), \(h_b\), \(h_c\)lần lượt là các đường cao hạ từ A , B , C. CHứng minh :
a) \(\sin\widehat{A}\)= k\(\left(\sin\widehat{B}-\sin C\right)\)
b)\(\frac{1}{h_a}=k\left(\frac{1}{h_b}-\frac{1}{h_c}\right)\)
Có \(\sin\widehat{A}=\frac{h_c}{b}=\frac{h_b}{c}=\frac{h_c-h_b}{b-c}=\frac{h_b-h_c}{\frac{a}{k}}=\frac{k\left(h_b-h_c\right)}{a}\) (1)
Lại có : \(\hept{\begin{cases}\sin\widehat{B}=\frac{h_c}{a}\\\sin\widehat{C}=\frac{h_b}{a}\end{cases}}\)\(\Rightarrow\)\(k\left(\sin\widehat{B}-\sin\widehat{C}\right)=\frac{k\left(h_c-h_b\right)}{a}\) (2)
(1) (2) ...
\(\sin\widehat{B}=\frac{h_a}{c}\)\(;\)\(\sin\widehat{C}=\frac{h_a}{b}\) (1)
\(\hept{\begin{cases}\sin\widehat{B}=\frac{h_c}{a}\\\sin\widehat{C}=\frac{h_b}{a}\end{cases}\Leftrightarrow\hept{\begin{cases}h_c=\sin\widehat{B}.a\\h_b=\sin\widehat{C}.a\end{cases}}}\)\(\Rightarrow\)\(k\left(\frac{1}{h_b}-\frac{1}{h_c}\right)=\frac{k}{a}.\left(\frac{1}{\sin\widehat{C}}-\frac{1}{\sin\widehat{B}}\right)\) (2)
Thay (1) vào (2) ta được \(\frac{k}{a}.\left(\frac{1}{\sin\widehat{C}}-\frac{1}{\sin\widehat{B}}\right)=\frac{k}{a}.\left(\frac{b}{h_a}-\frac{c}{h_a}\right)=\frac{k}{a}.\frac{\frac{a}{k}}{h_a}=\frac{1}{h_a}\)
đpcm
1. Cho tam giác $ABC$. Chứng minh rằng $\sin ^{2} A+\sin ^{2} B-\sin ^{2} C=2\sin A.\sin B.\cos C$.
2. Chứng minh rằng:
a. $\sin \alpha .\sin \left(\dfrac{\pi }{3} -\alpha \right).\sin \left(\dfrac{\pi }{3} +\alpha \right)=\dfrac{1}{4} \sin 3\alpha $
b. $\sin 5\alpha -2\sin \alpha \left({\rm cos} {\rm 4}\alpha +\cos 2\alpha \right)=\sin \alpha $
Cho A, B, C là 3 góc trong tam giác. Chứng minh rằng:
1, sin A + sin B - sin C = 4sin\(\dfrac{A}{2}\) sin \(\dfrac{B}{2}\)sin \(\dfrac{C}{2}\)
2, \(\dfrac{sinA+sinB-sinC}{cosA+cosB-cosC+1}=tan\dfrac{A}{2}tan\dfrac{B}{2}tan\dfrac{C}{2}\) (ΔABC nhọn)
3, \(\dfrac{cosA+cosB+cosC+3}{sinA+sinB+sinC}=tan\dfrac{A}{2}+tan\dfrac{B}{2}+tan\dfrac{C}{2}\)
GIÚP MÌNH VỚI!!!
1.
\(sinA+sinB-sinC=2sin\dfrac{A+B}{2}.cos\dfrac{A-B}{2}-sin\left(A+B\right)\)
\(=2sin\dfrac{A+B}{2}.cos\dfrac{A-B}{2}-2sin\dfrac{A+B}{2}.cos\dfrac{A+B}{2}\)
\(=2sin\dfrac{A+B}{2}.\left(cos\dfrac{A-B}{2}-cos\dfrac{A+B}{2}\right)\)
\(=2sin\dfrac{A+B}{2}.2sin\dfrac{A}{2}.sin\dfrac{B}{2}\)
\(=4sin\dfrac{A}{2}.sin\dfrac{B}{2}.cos\dfrac{C}{2}\)
Sao t lại đc như này v, ai check hộ phát
Cho \(\Delta ABC\) có BC=a, CA=b, AB=c và các đường cao tương ứng là \(h_a,h_b,h_c\) .Chúng minh :\(\dfrac{1}{h_a+h_b}+\dfrac{1}{h_b+h_c}+\dfrac{1}{h_c+h_a}\le\dfrac{a+b+c}{4S}\) (S là diện tích)
\(\dfrac{a.h_a}{2}=S\Leftrightarrow a=\dfrac{2S}{h_a}\)
Tương tự:
\(b=\dfrac{2S}{h_b};c=\dfrac{2S}{h_c}\)
\(\dfrac{a+b+c}{4S}=\dfrac{\dfrac{2S}{h_a}+\dfrac{2S}{h_b}+\dfrac{2S}{h_c}}{4S}=\dfrac{2S\left(\dfrac{1}{h_a}+\dfrac{1}{h_b}+\dfrac{1}{h_c}\right)}{4S}=\dfrac{\dfrac{1}{h_a}+\dfrac{1}{h_b}+\dfrac{1}{h_c}}{2}\)
Tương đương:
\(\dfrac{1}{h_a+h_b}+\dfrac{1}{h_b+h_c}+\dfrac{1}{h_c+h_a}\le\dfrac{\dfrac{1}{h_a}+\dfrac{1}{h_b}+\dfrac{1}{h_c}}{2}\)
Cauchy-Schwarz:
\(\dfrac{1}{h_a+h_b}\le\dfrac{1}{4}\left(\dfrac{1}{h_a}+\dfrac{1}{h_b}\right)\)
\(\dfrac{1}{h_b+h_c}\le\dfrac{1}{4}\left(\dfrac{1}{h_b}+\dfrac{1}{h_c}\right)\)
\(\dfrac{1}{h_c+h_a}\le\dfrac{1}{4}\left(\dfrac{1}{h_c}+\dfrac{1}{h_a}\right)\)
Cộng theo vế suy ra đpcm
Chứng minh rằng với mọi tam giác ABC ta có:
a) \(SinA+SinB+SinC\le Cos\dfrac{A}{2}+Cos\dfrac{B}{2}+Cos\dfrac{C}{2}\)
b) \(CosA.CosB.CosC\le Sin\dfrac{A}{2}.Sin\dfrac{B}{2}.Sin\dfrac{C}{2}\)