Integrated math 1
- Geometric constructions: congruent angles
- Geometric constructions: parallel line
- Geometric constructions: perpendicular bisector
- Geometric constructions: perpendicular line through a point on the line
- Geometric constructions: perpendicular line through a point not on the line
- Geometric constructions: angle bisector
- Justify constructions
We can construct congruent angles with a compass and straight edge. They're congruent corresponding angles of congruent triangles.
- [Instructor] What we're gonna do in this video is learn to construct congruent angles, and we're gonna do it, with of course, a pen or a pencil here. I'm gonna use a ruler as a straight edge. And then I'm gonna use a tool known as a compass. Which looks a little bit fancy, but what it allows us to do it'll apply using it in a little bit, is it allows us to draw perfect circles, or arcs, of a given radius. You pivot on one point here and then you use your pen or your pencil to trace out the arc, or the circle. So let's just start with this angle right over here, and I'm going to construct an angle that is congruent to it. So let me make the vertex of my second angle right over there, and then let me draw one of the rays that originates at that vertex. And I'm gonna put this angle in a different orientation, just to show that they don't even have to have the same orientation. So it's going to look something like that, that's one of the rays. But then we have to figure out where do we put, where do we put the other ray so that the two angles are congruent? And this is where our compass is going to be really useful. So what I'm going to do is put the pivot point of a compass, of the compass, right at the vertex of the first angle, and I'm going to draw out an arc like this. And what's useful about the compass is you can keep the radius constant, and you can see it intersects our first two rays at points, let's just call this B and C. And I could call this point A, right over here. And so let me, now that I have my compass with the exact right radius right now, let me draw that right over here. But this alone won't allow us to draw the angle just yet, but let me draw it like this, and that is pretty good. And let's call this point right over here D, and I'll call this one E, and I wanna figure out where to put my third point F, so I can define ray E F, so that these two angles are congruent. And what I can do is take my compass again and get a clear sense of the distance between C and B, by adjusting my compass. So one point is on C, and my pencil is on B. So I have, get this right, so I have this distance right over here. I know this distance, and I've adjusted my compass accordingly, so I can get that same distance right over there. And so you can now image where I'm going to draw that second ray. That second ray, if I put point F right over here, my second ray, I can just draw between, starting at point E right over here, going through point F. I could draw a little bit neater, so it would look like that, my second ray. Ignore that first little line I drew, I'm using a pen, which I don't recommend for you to do it. I'm doing it so that you can see it on this video. Now how do we know that this angle is now congruent to this angle right over here? Well one way to do it, is to think about triangle B A C, triangle B A C, and triangle, let's just call it D F E. So this triangle right over here. When we drew that first arc, we know that the distance between A C is equivalent to the distance between A B, and we kept the compass radius the same. So we know that's also the distance between E F, and the distance between E D. And then the second time, when we adjusted our compass radius, we now know that the distance between B C is the same as the distance between F and D. Or the length of B C is the same as the length of F D. So it's very clear that we have congruent triangles. All of the three sides have the same measure, and therefore the corresponding angles must be congruent as well.