tag:blogger.com,1999:blog-6933544261975483399.post3675464489180405808..comments2024-03-26T19:10:02.918-07:00Comments on Go Geometry (Problem Solutions): Problem 340. Triangle, Angle Bisectors, Perpendiculars, Exterior Point, Distances.Antonio Gutierrezhttp://www.blogger.com/profile/04521650748152459860noreply@blogger.comBlogger4125tag:blogger.com,1999:blog-6933544261975483399.post-16887518743441615982015-12-25T19:53:21.071-08:002015-12-25T19:53:21.071-08:00See below for the sketch of pro. 340
http://s2.pos...See below for the sketch of pro. 340<br />http://s2.postimg.org/dpyy7jsy1/pro_340.png<br /><br />Peter TranPeter Tranhttps://www.blogger.com/profile/02320555389429344028noreply@blogger.comtag:blogger.com,1999:blog-6933544261975483399.post-19597534668498417092010-06-29T12:27:24.449-07:002010-06-29T12:27:24.449-07:00Here is the geometry solution to the problem:
1.C...Here is the geometry solution to the problem:<br /><br />1.Call Points M1, H1 as the projections of point E over segments AC and BC<br /> Call Points M2, G1 as the projections of point D over segments AC and AB<br /> Let x=EF and X=ED<br />2. We have EM1=EH1 ( EC is angle bisector of angle ACB)<br /> DM2=DG1 (AD is angle bisector of angle BAC)<br />3.calculate FM as linear interpolation (or similar triangles)of EM1 and DM2 <br />(EM1-FM)/(DM2-FM)= x/(X+x)<br />So FM= x/X*DM2 +(X+x)/X *EM1<br />4.Triangle FGE similar to triangle DG1E and we have <br />FG/DG1= x/X so FG=x/X *DG1<br />5.Triangle DH1E simillar to triangle DGF and we have <br />FH/FH1= (x+X)/X so FH= (x+X)/X *EH1<br /><br />6.FH+FG= x/X *DG1 +(x+X)/X *EH1<br />7.Replace DG1=DM2 and EH1=EM1 we get<br />FH+FG=x/X *DM2+(X+x)/X *EM1= FM per step 3<br /> So FM=FH-FG<br /><br />Peter Tran <br />Emai : vstran@yahoo.comPeter Tranhttps://www.blogger.com/profile/02320555389429344028noreply@blogger.comtag:blogger.com,1999:blog-6933544261975483399.post-28029148760877670002010-06-28T15:20:55.373-07:002010-06-28T15:20:55.373-07:00I am interest in geometry solution not algebrica
...I am interest in geometry solution not algebrica<br />solution. Anybody have geometry solution ? <br /><br />Peter Tran<br />vstran@yahoo.comPeter Tranhttps://www.blogger.com/profile/02320555389429344028noreply@blogger.comtag:blogger.com,1999:blog-6933544261975483399.post-25454530210947149042009-08-25T23:06:43.631-07:002009-08-25T23:06:43.631-07:00As in problem # 339, we assume B:(p,q), A:(0,0) &a...As in problem # 339, we assume B:(p,q), A:(0,0) & C:(b,0)and AB = c, AC = b & BC = a as usual.<br />Since E divides AB in the ratio b:a we've<br />E as(bp/(a+b), bq/(a+b))<br />Since D divides CB in the ratio b:c<br />D is ((bp+bc)/(b+c), bq/(b+c))<br />Slope DE =((bq/(a+b))- bq/(b+c)) /(bp/(a+b)- (bp+bc)/(b+c)) = (c-a)q/(c(b-p)+a(c+p))<br />DE is y = (c-a)qx/(cb+ac+pa-pc) + k and k can be determined as bqc/(cb+ac+pa-pc)since the line passes thru E by substituting co-ordinates of D in the eqn. above. Thus,DE is:<br />y=((c-a)qx+bqc)/(cb+ac+pa-pc)-------(1)<br />Let F:(x,y) be any point on DE extended satisfying the eqn. above. <br />Now AB is y=qx/p or qx-py=0 while AC is y=0<br />Slope BC = -q/(b-p)<br />Hence BC is y= -qx/(b-p) + k1 & it passes thru’ (b,0) so k1 = qb/(b-p). Hence BC is qx + y(b-p)-qb=0. Therefore, FG = qx-py/c since c^2 = p^2+q^2<br />& FH = (qx +y(b-p)-qb)/a since a^2 =(b-p)^2+q^2<br />We observe that FG and FH are of the same sign while FM is of the opposite sign.{If c > 0 in the equation ax + by + c = 0 of the straight line and the given point and the origin are on the same side of the given straight line, then the required length of the perpendicular is positive and if the given point and the origin are on the opposite sides of the given straight line, then the perpendicular distance will be negative}<br />Hence, FH -FG = (qx +y(b-p) -qb)/a - (qx-py)/c <br />If this is equated to FM = - y then we obtain<br />y = ((c-a)qx+bqc)/(cb+ac+pa-pc) which is, in fact, equation (1) above. Therefore for any point F on extended DE we’ve: FH - FG = FM .QED.<br />AjitAjithttps://www.blogger.com/profile/00611759721780927573noreply@blogger.com