Expressing Vector SM: A Tetrahedron Geometry Problem

by ADMIN 53 views

Hey math enthusiasts! Let's dive into a cool geometry problem involving a tetrahedron and vector expressions. We'll be focusing on expressing a specific vector within the tetrahedron using other given vectors. It might seem tricky at first, but with a step-by-step approach, we'll break it down and make it super understandable. So, grab your pencils and let's get started!

Understanding the Problem: The Tetrahedron and Vectors

First off, let's get acquainted with the setup. We're dealing with a tetrahedron, which is essentially a 3D shape with four triangular faces. Think of it like a pyramid, but with a triangular base. We're given a tetrahedron named SABC. The problem introduces a few key points: N is the midpoint of edge AC, M lies on the line segment BN, and a crucial vector relationship BM⃗=23BN⃗\vec{BM} = \frac{2}{3} \vec{BN}. Our goal? Express the vector SM⃗\vec{SM} using the vectors a⃗=BA⃗\vec{a} = \vec{BA}, b⃗=BS⃗\vec{b} = \vec{BS}, and c⃗=BC⃗\vec{c} = \vec{BC}. This means we need to find a way to write SM⃗\vec{SM} as a combination of these three vectors. Remember, vectors have both magnitude and direction, and we can add and scale them to move around the tetrahedron.

Let's break down this problem. We are given the vectors aβƒ—=BAβƒ—\vec{a} = \vec{BA}, bβƒ—=BSβƒ—\vec{b} = \vec{BS}, and cβƒ—=BCβƒ—\vec{c} = \vec{BC}. Our objective is to determine a linear combination of these vectors that equals SMβƒ—\vec{SM}. The point N is the midpoint of AC. The point M is positioned on BN such that BMβƒ—=23BNβƒ—\vec{BM} = \frac{2}{3} \vec{BN}. This setup provides us with a clear roadmap to expressing SMβƒ—\vec{SM}. First, we will express BNβƒ—\vec{BN} using vectors aβƒ—\vec{a} and cβƒ—\vec{c}, since N lies on AC. Next, we will use the relation BMβƒ—=23BNβƒ—\vec{BM} = \frac{2}{3} \vec{BN} to find BMβƒ—\vec{BM}. Then, we will find SMβƒ—\vec{SM} using vectors SBβƒ—\vec{SB} and BMβƒ—\vec{BM}. This problem requires a solid understanding of vector addition and scalar multiplication. We will meticulously go through each step, making sure every concept is clear and easy to follow. Remember, understanding the given information and visualizing the spatial relationships are crucial in these types of problems. Now, let’s get into the step-by-step solution.

Step-by-Step Solution: Unraveling the Vector Expression

Step 1: Expressing Vector BN

Since N is the midpoint of AC, we can express ANβƒ—\vec{AN} as 12ACβƒ—\frac{1}{2} \vec{AC}. Now, let's express ACβƒ—\vec{AC} in terms of the given vectors. We know that ACβƒ—=ABβƒ—+BCβƒ—\vec{AC} = \vec{AB} + \vec{BC}. Also, ABβƒ—=βˆ’BAβƒ—=βˆ’aβƒ—\vec{AB} = -\vec{BA} = -\vec{a}. Therefore, ACβƒ—=βˆ’aβƒ—+cβƒ—\vec{AC} = -\vec{a} + \vec{c}. Now, we have ANβƒ—=12(βˆ’aβƒ—+cβƒ—)\vec{AN} = \frac{1}{2} ( -\vec{a} + \vec{c}). To find BNβƒ—\vec{BN}, we use the fact that BNβƒ—=BAβƒ—+ANβƒ—\vec{BN} = \vec{BA} + \vec{AN}. Substituting the values, we get BNβƒ—=aβƒ—+12(βˆ’aβƒ—+cβƒ—)=βˆ’aβƒ—+12cβƒ—\vec{BN} = \vec{a} + \frac{1}{2} (-\vec{a} + \vec{c}) = -\vec{a} + \frac{1}{2} \vec{c}. So, BNβƒ—\vec{BN} is now expressed in terms of aβƒ—\vec{a} and cβƒ—\vec{c}. We've successfully navigated the first part of our journey. This step demonstrates the application of basic vector addition and the properties of a midpoint. The core idea is to break down complex vectors into simpler components that we can easily manipulate using the given information. Keep an eye on the directions and signs of the vectors – this is super important.

Step 2: Finding Vector BM

We are given that BMβƒ—=23BNβƒ—\vec{BM} = \frac{2}{3} \vec{BN}. From Step 1, we know the expression for BNβƒ—\vec{BN}. Substituting this, we get BMβƒ—=23(βˆ’aβƒ—+12cβƒ—)=βˆ’23aβƒ—+13cβƒ—\vec{BM} = \frac{2}{3} ( -\vec{a} + \frac{1}{2} \vec{c}) = -\frac{2}{3} \vec{a} + \frac{1}{3} \vec{c}. So, BMβƒ—\vec{BM} is now expressed in terms of aβƒ—\vec{a} and cβƒ—\vec{c}. This part is straightforward but super crucial. We're using the given ratio to scale the vector BNβƒ—\vec{BN}. This is an example of scalar multiplication of vectors, another fundamental concept. Make sure you don't miss any coefficients or signs during the multiplication, as even a small mistake can lead to a wrong answer. We’re getting closer to our final goal.

Step 3: Expressing Vector SM

To find SMβƒ—\vec{SM}, we can use the following relationship: SMβƒ—=SBβƒ—+BMβƒ—\vec{SM} = \vec{SB} + \vec{BM}. We know that SBβƒ—=βˆ’BSβƒ—=βˆ’bβƒ—\vec{SB} = -\vec{BS} = -\vec{b}. From Step 2, we have BMβƒ—=βˆ’23aβƒ—+13cβƒ—\vec{BM} = -\frac{2}{3} \vec{a} + \frac{1}{3} \vec{c}. Substituting these values, we get SMβƒ—=βˆ’bβƒ—+(βˆ’23aβƒ—+13cβƒ—)=βˆ’23aβƒ—βˆ’bβƒ—+13cβƒ—\vec{SM} = -\vec{b} + (-\frac{2}{3} \vec{a} + \frac{1}{3} \vec{c}) = -\frac{2}{3} \vec{a} - \vec{b} + \frac{1}{3} \vec{c}. This is it, guys! We have expressed SMβƒ—\vec{SM} in terms of aβƒ—\vec{a}, bβƒ—\vec{b}, and cβƒ—\vec{c}!

This final step brings everything together. We combine our previous findings to express the vector we were originally asked to find. Notice how we systematically broke down the problem into smaller, manageable steps. This approach is really effective for solving complex vector problems. By expressing SM⃗\vec{SM} as a linear combination of a⃗\vec{a}, b⃗\vec{b}, and c⃗\vec{c}, we have successfully completed the problem. Double-check your calculations to make sure everything is perfect.

Conclusion: Vector Mastery

And there you have it! We've successfully expressed the vector SMβƒ—\vec{SM} in terms of aβƒ—\vec{a}, bβƒ—\vec{b}, and cβƒ—\vec{c}. This problem highlights the power of vector addition, scalar multiplication, and the importance of breaking down complex problems into smaller, manageable steps. Remember, with practice, you'll become more confident in handling these kinds of problems. Keep practicing, and you'll become a vector wizard in no time! Also, visualizing the problem helps. If you're struggling, try drawing the tetrahedron and marking the vectors to see the relationships more clearly. Finally, don’t hesitate to revisit the basics, vector addition, and scalar multiplication, as they are the building blocks of any vector-related concept.

In summary, the key steps were:

  1. Finding BN⃗{\vec{BN}}: We used the midpoint property and vector addition to express BN⃗{\vec{BN}} in terms of a⃗{\vec{a}} and c⃗{\vec{c}}.
  2. Finding BM⃗{\vec{BM}}: We used the given ratio BM⃗=23BN⃗{\vec{BM} = \frac{2}{3} \vec{BN}} and scalar multiplication.
  3. Finding SM⃗{\vec{SM}}: We used the relationship SM⃗=SB⃗+BM⃗{\vec{SM} = \vec{SB} + \vec{BM}} and expressed SM⃗{\vec{SM}} as a linear combination of a⃗{\vec{a}}, b⃗{\vec{b}}, and c⃗{\vec{c}}.

Keep up the great work, and happy vectoring! You're doing amazing, and keep practicing! If you have any questions or want to try another problem, feel free to ask. This approach allows us to solve the problem systematically, ensuring that we utilize all the given information efficiently. By expressing the vector SM⃗\vec{SM} as a combination of other known vectors, we have successfully addressed the original challenge. Remember to review each step and practice similar problems to solidify your understanding. The key is to start with a solid foundation and carefully build upon it, one step at a time. Congratulations on making it through, and keep up the fantastic work! Keep exploring more geometric problems and enjoy the world of mathematics.