Stephen Friedberg

Linear Algebra 5th Edition Chapter 1 Vector Spaces

Page 54 Problem 1 Answer

Here, the zero vector space has some basis. So the statement is false.

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

A vector that has a magnitude equal to zero is called a zero vector.

Considering the definitions of zero vector and vector.

The vector is a property or quantity that has both magnitude and direction.

So even if the magnitude is zero, a vector still holds some significance because of its direction.

Therefore a zero vector space has some basis.

A vector is defined by two parameters.

So, even if one is zero the other still holds some significance. Therefore the statement is can not true.

Therefore given statement “the zero vector space has no basis” is false.

Linear Algebra 5th Edition Chapter 1 Page 54 Problem 2 Answer

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Page 54 Problem 3 Answer

Every vector has an infinite base. So the statement is false.

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

The vector is a property or quantity that has both magnitude and direction.

So even if the direction is fixed, a vector also holds some significance because of its magnitude that can have any value.

Therefore a vector space has an infinite basis.

A vector is defined by two parameters.

So, even if one is fixed the other still can change.

Therefore the statement is can not true.

Therefore the given statement “every vector space has a finite basis” is false.

Chapter 1 Exercise 1.6 Vector Spaces Solved Examples Page 54 Problem 4 Answer

The zero vector space has some basis. So the statement is false.

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

The vector is a property or quantity that has both magnitude and direction.

So even if one property is fixed and can have only one definition, the other can have multiple definitions.

Therefore a zero vector space has some basis.

A vector is defined by two parameters.

The vector’s basis depends on both these parameters.

So, the statement is not true.

Therefore the given statement “a vector space cannot have more than one basis” is false.

Page 54 Problem 5 Answer

For a vector space of finite basis, the number of vectors in every basis is the same.

So the statement is true. A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

For a vector space that has a finite basis, all parameters defining the space are fixed.

So, for every basis in it, the number of vectors will be the same.

The entire space is finite.

Therefore, if a vector space has a finite basis, then the number of vectors in every basis is the same.

The vector space is finite.

So the statement is not false.

Therefore the given statement “if a vector space has a finite basis, then the number of vectors in every basis is the same” is true.

Linear Algebra 5th Edition Chapter 1 Page 54 Problem 6 Answer

The dimension of Pn(F) is n+1. So the given statement is false.

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

From the replacement theorem we know that, for a finite-dimensional vector space, there is no linearly independent vector subset of it that can contain more vectors than its own dimension.

Following this, we can say that as we do not know the value of n the given vector space becomes an infinite-dimensional vector space.

So, the dimension of Pn(F) is n+1 as the dimension of a vector space depends on its field of scalars.

The dimension of a vector space depends on its field of scalars. So the statement is not true.

Therefore the given statement “the dimension of P(n) is n” is false.

Page 54 Problem 7 Answer

The dimensions of Mm×n(F) is mn.

So the statement is false.

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

From the replacement theorem we know that, for a finite-dimensional vector space, there is no linearly independent vector subset of it that can contain more vectors than its own dimension.

The replacement theorem also gives a heavy wealth of information about dimensions of vector spaces.

So, from the replacement theorem, the dimension of Mm×n(F) is mn.

The dimension of Mm×n(F) is mn and not m+n. So the statement is not true.

Therefore the given statement “the dimension of Mm×n

(F) is m+n” is false.

Vector Spaces Exercise 1.6 Explained Friedberg Chapter 1 Page 54 Problem 8 Answer

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

From the replacement theorem we know that, for a finite-dimensional vector space, there is no linearly independent vector subset of it that can contain more vectors than its own dimension.

Hence, for any finite-dimensional vector space V, if S1 is a linearly independent subset of V and S2 is a subset of V that generates it, then the number of vectors in S1 is always less than number of vectors in S2.So the statement is true.

A linearly independent subset has less vector in comparison to the generating subset. So the statement is not false.

Therefore the given statement “suppose that V is a finite-dimensional vector space, that S1 is a linearly independent subset of V, and that S2 is a subset of V that generates V.

Then S1 cannot contain more vectors than S2 ” is true.

Linear Algebra 5th Edition Chapter 1 Page 54 Problem 9 Answer

If S is a linearly independent set that generates V, then the vectors in V can be written as combinations of vectors in S in only one way.

So the given statement is true.

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

Using the replacement theorem we know that, for a finite-dimensional vector space, no linearly independent vector subset of it can contain more vectors than its own dimension for a finite-dimensional vector space.

If S is a linearly independent vector space.

The for the vector space V that it generates, every vector in V

can be written as a linear combination of the vector in S but only in one way.

We know S is a linearly independent set. But, if S was not linearly independent then the statement would have been false.

So the statement is not false.

Therefore the given statement “if S generates the vector space V, then every vector in V can be written as a linear combination of vectors in S in only one way” is true.

Linear Algebra 5th Edition Chapter 1 Page 54 Problem 10 Answer

The subset of a finite-dimensional set is a finite-dimensional space.

So the statement is true.

A premise of a vector space is a most extreme straightly autonomous subset of it.

Each vector space has a premise. (It very well may be limited or boundless.) and each premise of a vector space has similar number of components.

The measurement a vector space is the quantity of components in any of its bases.

Each directly free subset of a vector space can be reached out to a premise.

Therefore, the quantity of components in a directly free subset of a vector space is not exactly or equivalent to its measurement.

It is practically impossible for a subset of a finite-dimensional set to be an infinite-dimensional set. Therefore the statement is not false.

Therefore the given statement “every subspace of a finite-dimensional space is finite-dimensional” is true.

Linear Algebra 5th Edition Chapter 1 Page 54 Problem 11 Answer

A vector is a quantity that has a magnitude and direction.

There are different types of vectors.

From the replacement theorem we know that, for a finite-dimensional vector space, there is no linearly independent vector subset of it that can contain more vectors than its own dimension.

The subspace of V with dimensions 0 is given as {0} and subspace with dimension n is V.

The statement is true.

The subspace with dimensions 0 is {0} and the subspace with dimension is V.

Therefore the statement is not false.

Therefore the given statement is true.

Linear Algebra 5th Edition Chapter 1 Page 54 Problem 12 Answer

A vector is a quantity that has a magnitude and direction. There are different types of vectors.

From the replacement theorem we know that, for a finite-dimensional vector space, there is no linearly independent vector subset of it that can contain more vectors than its own dimension.

Here,S can be a spanning set of V only if SpanS=V.So, If V is a vector space having dimension n, and if S is a subset of V with n vectors, then S is linearly independent if and only if S spans V.

The statement is true.

It could be false if SpanS≠V. Therefore the statement is not false.

Therefore the given statement “if V is a vector space having dimension n, and if S is a subset of V with n vectors, then S is linearly independent if and only if S spans V” is true.

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 13 Answer

Given that {(1,0,−1),(2,5,1),(0,−4,3)} n the hypothesis of vector spaces, a bunch of vectors is supposed to be directly reliant in case there is a nontrivial straight mix of the vectors that approaches the zero vector.

On the off chance that no such direct mix exists, the vectors are supposed to be straightly autonomous.

These ideas are key to the meaning of measurement.

For bases of R3 the set must be linearly independent.

Use the relation for linearly independent to conclude the final answer.

Given that:

⇒ S={(1,0,−1),(2,5,1),(0,−4,3)}

For S to be the base of R3 it must be a linearly independent set.

Thus, for linearly independent set we have,

⇒ a1(1,0,−1)+a2(2,5,1)+a3(0,−4,3)=0

Solving further;

⇒ a1(1,0,−1)+a2(2,5,1)+a3(0,−4,3)=0

⇒ a1+2a2=0 ……(1)

⇒ 5a2−4a3=0 ……(2)

⇒ −a1+a2+3a3=0 ……(3)

Adding the equations (1),(2) and (3),

8a2−a3=0

This implies that,a2=0

As a result a1=a3

Thus,

⇒ a1=0

⇒ a3=0

Thus, the given set is a base of R3.

The given set is a bases of R3.

Friedberg 5th Edition Chapter 1 Exercise 1.6 Guide Page 55 Problem 14 Answer

Given that {(2,−4,1),(0,3,−1),(6,0,−1)}

In the hypothesis of vector spaces, a bunch of vectors is supposed to be directly reliant in case there is a nontrivial straight mix of the vectors that approaches the zero vector.

On the off chance that no such direct mix exists, the vectors are supposed to be straightly autonomous.

These ideas are key to the meaning of measurement.

For bases of R3 the set must be linearly independent.

Use the relation for linearly independent to conclude the final answer.

Given that: S={(2,−4,1),(0,3,−1),(6,0,−1)}

For S to be the base of R3 it must be a linearly independent set.

For linearly independent set we have,

⇒ a1(2,−4,1)+a2(0,3,−1)+a3(6,0,−1)=0

Solving further,

⇒ a1(2,−4,1)+a2(0,3,−1)+a3(6,0,−1)=0

⇒2a1+6a3=0 ……(1)

⇒−4a1+3a2=0 ……(2)

⇒a1−a2−a3=0 ……(3)

Adding the equations (1),(2) and (3)

we get,−a1+2a2+5a3=0

⇒ a1=2a2+5a3

The above equation is satisfied for the following values;

⇒ a1=3

⇒ a2=4

⇒ a3=−1

Thus, the given set is not a base of R3.

The given set is not a base of R3.

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 15 Answer

Given that {(1,2,−1),(1,0,2),(2,1,1)}

In the hypothesis of vector spaces, a bunch of vectors is supposed to be directly reliant in case there is a nontrivial straight mix of the vectors that approaches the zero vector.

On the off chance that no such direct mix exists, the vectors are supposed to be straightly autonomous.

These ideas are key to the meaning of measurement.

For bases of R3 the set must be linearly independent.

Use the relation for linearly independent to conclude the final answer.

Given that:S={(1,2,−1),(1,0,2),(2,1,1)}

For S to be a base of R3

we have,

⇒ a1(1,2,−1)+a2(1,0,2)+a3(2,1,1)=0

Solving further;

⇒ a1(1,2,−1)+a2(1,0,2)+a3(2,1,1)=0

⇒a1+a2+2a3=0 ……(1)

⇒2a1+a3=0 ……(2)

⇒−a1−2a2+a3=0 ……(3)

​Adding the equations (1),(2) and (3)

we get,

⇒ 2a1−a2+4a3=0

⇒ a2=2a1+4a3

The above equation is true only if all the scalars are zero.

Thus, the given set is a base of R3 for the above condition.

The given set is a bases of R3.

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 16 Answer

Given that {(−1,3,1),(2,−4,−3),(−3,8,2)}

In the hypothesis of vector spaces, a bunch of vectors is supposed to be directly reliant in case there is a nontrivial straight mix of the vectors that approaches the zero vector.

On the off chance that no such direct mix exists, the vectors are supposed to be straightly autonomous.

These ideas are key to the meaning of measurement.

For bases of R3 the set must be linearly independent.

Use the relation for linearly independent to conclude the final answer.

Given that:

⇒ S={(−1,3,1),(2,−4,−3),(−3,8,2)}

For the given set to be the base of R3

we have,

⇒ a1(−1,3,1)+a2(2,−4,−3)+a3(−3,8,2)=0

Solving further;

⇒ a1(−1,3,1)+a2(2,−4,−3)+a3(−3,8,2)=0

⇒−a1+2a2−3a3=0 ……(1)

⇒3a1−4a2+8a3=0 ……(2)

⇒a1−6a2+2a3=0 ……(3)

​Adding equations (1),(2) and (3) we get,3a1−8a2+7a3=0

The above equation is only possible for the scalars to be zero.

Thus, the given set is a base of R3 only for the above condition.

The given set is a bases of R3.

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 17 Answer

Given that {(1,−3,−2),(−3,1,3),(−2,−10,−2)}

In the hypothesis of vector spaces, a bunch of vectors is supposed to be directly reliant in case there is a nontrivial straight mix of the vectors that approaches the zero vector.

On the off chance that no such direct mix exists, the vectors are supposed to be straightly autonomous.

These ideas are key to the meaning of measurement.

For bases of R3 the set must be linearly independent.

Use the relation for linearly independent to conclude the final answer.

Given that:

⇒ S={(1,−3,−2),(−3,1,3),(−2,−10,−2)}

For the given set to be a base of R3

we have,

⇒ a1(1,−3,−2)+a2(−3,1,3)+a3(−2,−10,−2)=0

Solving further,

⇒ a1(1,−3,−2)+a2(−3,1,3)+a3(−2,−10,−2)=0

⇒a1−3a2−2a3=0 …(1)

⇒−3a1+a2−10a3=0 …(2)

⇒−2a1+3a2−2a3=0 …(3)

​Adding equations (1),(2) and (3)

we get,−4a1+a2−14a3=0

⇒ a2=4a1+14a3

The above equation is true only if all scalars are zero.

The given set is a base of R3 for the above condition.

The given set is a base of R3.

Exercise 1.6 Notes From Friedberg Linear Algebra 5th Edition Chapter 1 Page 55 Problem 18 Answer

Given, {−1−x+2×2,2x+x−2×2,1−2x+4×2}.Determine which of the following sets are basis for P2(R).

Using dimensions and results will get.

The dim of (P2(R))=3.

∴, The set is a basis for P2(R) if it contains three linearly independent vectors.

The sets are α(−1−x+2×2)+β(2+x−2×2)+γ(1−2x+4×2)=0

⇒ (−α+2β+γ)+(−α+β−2γ)x+(2α−2β+4γ)x2=0

⇒ −α+2β+γ=0……..(1)

⇒ −α+β−2γ=0……..(2)

⇒ 2α−2β+4γ=0…….(3)

Subtract (1) from (2) equation also multiply (1) equation by 2 and add (1) and (3) equation.

⇒ −α+2β+γ=0……..(4)

⇒ −β−3γ=0……….(5)

⇒ 2β+5γ=0……….(6)

Multiply (5) equation by 2 and add (5) and (6) equation.

⇒ −α+2β+γ=0

⇒ −β−3γ=0

⇒ 0=0

⇒ α=7t

⇒ β=−3t

⇒ γ=t∀t∈R

{−1−x+2×2,2+x−2×2,1−2x+4×2} is linearly independent.

The set is not a basis for P2(R).

Hence, the set is not a basis for P2(R).

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 19 Answer

Given, {1+2x+x2,3+x2,x+x2}.Determine which of the following sets are basis for P2(R).Using dimensions and results will get.

The dim (P2(R))=3.

∴, The set is a basis for P2(R) if it contains three linearly independent vectors.

The set is α(1+2x+x2)+β(3+x2)+γ(x+x2)=0

(α+3β)+(2α+γ)x+(α+β+γ)x2=0 α+3β=0……….(1)

⇒ 2α+γ=0……….(2)

⇒ α+β+γ=0…….(3)

Multiply (1) equation by 2 and subtract (1) from (2) and then subtract (1) from (3).

⇒ α+3β=0………..(4)

⇒ −6β+γ=0……….(5)

⇒ −2β+γ=0……….(6)

Subtract (5) from (6).

⇒ α+3β=0

⇒ −6β+γ=0

⇒ 4β=0

⇒ α=0

⇒ β=0

⇒ γ=0

{(1+2x+x2)+(3+x2)+(x+x2)} is a linearly independent set of three vectors.

The set is not a basis for P2(R).

Hence, the set is not a basis for P2(R).

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 20 Answer

Given, {1−2x−2×2,−2+3x−x2,1−x+6×2}.Determine which of the following sets are basis for P2(R).

Using dimensions and results will get.

The dim (P2(R))=3.

∴, The set is a basis for P2(R) if it contains three linearly independent vectors.

The set is α(1−2x−2×2)+β(−2+3x−x2)+γ(1−x+6×2)=0

(α−2β+γ)+(−2α+3β−γ)x+(−2α−β+6γ)x2=0

⇒ α−2β+γ=0……….(1)

⇒ −2α+3β−γ=0……….(2)

⇒ −2α−β+6γ=0……….(3)

Multiply (1) equation by 2 and add (1) and (2)and then multiplying (1) equation by 2 and add (1) and (2).

⇒ α−2β+γ=0…………(4)

⇒ −β+γ=0…………(5)

⇒ −5β+8γ=0………..(6)

Multiplying (5) equation by 5 and subtract (5) from (6).

⇒ α−2β+γ=0

⇒ −β+γ=0

⇒ 3γ=0

⇒ α=0

⇒ β=0

⇒ γ=0

{1−2x−2×2,−2+3x−x2,1−x+6×2}is a linearly independent set of three vectors.

The set is a basis for P2(R).

Hence, the set is a basis for P2(R).

Study Resources For Chapter 1 Exercise 1.6 Vector Spaces Chapter 1 Page 55 Problem 21 Answer

Given, {1+2x+4×2,3−4x−10×2,−2−5x−6×2}.Determine which of the following sets are basis for P2(R).

Using dimensions and results will get.

The dim P2(R).

∴, The set is a basis for P2(R)if it contains three linearly independent vectors.

The set is α(−1+2x+4×2)+β(3−4x−10×2)+γ(−2−5x−6×2)=0

(−γ+3β−2γ)+(2α−4β−5γ)x+(4α−10β−64)x2=0

⇒ α+3β−2γ=0………(1)

⇒ 2α−4γ−5γ=0……….(2)

⇒ 4α−10β−6γ=0………(3)

Multiply (1) equation by 2 and add (1) and (2) equation multiplication (1) equation by 4 and add (1) and (3)equation.

⇒ −α+3β−2γ=0……….(4)

⇒ 2β−9γ=0………..(5)

⇒ 2β−14γ=0………(6)Subtract (5) from (6).

⇒ −α+3β−2γ=0

⇒ 2β−9γ=0

⇒ −5γ=0

{−1+2x+4×2,3−4x−10×2,−2−5x−6×2} is a linearly independent set of three vectors.

The set is a basis for P2(R).

Hence, the set is a basis for P2(R).

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 22 Answer

Given, {1+2x−x2,4−2x+x2,−1+18−9×2}.Determine which of the following sets are basis for P2(R).

Using dimensions and results will get.

The dim (P2(R))=3.

∴, The set is a basis for P2(R) if it contains three linearly independent vectors.

he set isα(1+2x−x2)+β(4−2x+x2)+γ(−1+18x−9×2)=0

(α+4β−γ)+(2α−2β+18γ)x+(−α+β−9γ)x2=0

α+4β−γ=0……….(1)

2α−2β+18γ=0……….(2)

−α+β−9γ=0………..(3)

Multiply (1) equation by 2 and subtract (1) from (2) equation then add (1) and (3) equation.

α+4β−γ=0………..(4)

−10β+20γ=0……….(5)

5β−10γ=0………..(6)

Multiply (6) equation by (2) and add (5) and (6).

⇒ α+4β−γ=0

⇒ 0=0

⇒ 5β−10γ=0

⇒ α=−7t,

⇒ β=2t

⇒ γ=t∀t∈R

{1+2x−x2,4−2x+2×2,−1+18x−9×2} is linearly independent.

The set is not a basis for P2(R).

Hence, the set is not a basis for P2(R).

Page 55 Problem 23 Answer

Given, If {(1,4,−6),(1,5,8)(2,1,1)(0,1,0)} a linearly independent subset of R3 .Justify your answer.

Any linearly independent set which generates a vector space will have less number of vectors than the dimension of vector space.

R3 is a 3− dimensional vector space.

Hence, these cannot be a set of 4 linearly independent vectors in R3.

Hence, there cannot be a set of 4 linearly independent vectors in R3.

Linear Algebra 5th Edition Chapter 1 Page 55 Problem 24 Answer

We are given, u1=(2,−3,1)

⇒ u2=(1,4,−2)

⇒ u3=(−8,12,−4)

⇒ u4=(1,37,−17)

⇒ u5=(−3,−5,8) generate R3.

We have to find a subset of the set {u1,u2,u3,u4,u5} that is a basis for R3.

We check independence of u1 and u2.

αu1=u2

⇒  α(2,−3,1)=(1,4,−1)

⇒ 2α=1,

−3α=4

α=−2 (not possible)

⇒{u1,u2} is linearly dependent.

We check independence of u1,u2 and u3.

αu1+βu2=u3

⇒ α(2,−3,1)+β(1,4,−2)=(−8,12,−4)

⇒(2α+β,−3α+4β,α−2β)=(−8,12−4)

2α+β=−8

−3α+4β=12

α−2β=−4

solving these we get,

β=0

α=−4

⇒ the set {u1,u2,u3} is not linearly independent.

We check independence of u1,u2, and u4.

αu1+βu2=u4​

⇒ α(2,−3,1)+β(1,4,−1)=(1,37,−17)

⇒ (2α+β,−3α+4β,α−2β)=(1,37,−17)

⇒ 2α+β=1,

−3α+4β=37,

α−2β=−17

solving these we get,    β=7,  α=−3

the set {u1,u2,u3}is not linearly independent.

We check independence of u1,u2 and u5.

αu1+βu2=u5

⇒α(2,−3,1)+β(1,4,−2)=(−3,−5,8)

⇒(2α+β,−3α+4β,α−2β)=(−3,−5,8)

⇒ 2α+β=−3,

−3α+4β=−5,

α−2β=8

From first two equations, we get

β=−7/5 and from first and third equation, we get

β=−19/5. This is not possible.

Therefore, the set {u1,u2,u5} is linearly independent, so, this forms our basis for R3

A subset of the set {u1,u2,u3,u4,u5} that forms a basis for R3 is {u1,u2,u5} or {(2,−3,1),(1,4,−2),(−3,−5,8)}.

Examples of Exercise 1.6 In Friedberg Linear Algebra Chapter 1 Page 55 Problem 25 Answer

We are given vectors, u1=(2,−3,4,−5,2),

⇒ u2=(−6,9,−12,15,−6),

⇒ u3=(3,−2,7,−9,1),

⇒ u4=(2,−8,2,−2,6),

⇒ u5=(−1,1,2,1,−3),

⇒ u6=(0,−3,−18,9,12),

⇒ u7=(1,0,−2,3,−2), and

⇒ u8=(2,−1,1,−9,7).

We have to find a subset of the set {u1,u2,u3,u4,u5} that is a basis for W, where W′ is a subspace for R5.

We check independence of u1 and u2.

αu1=u2

⇒α(2,−3,4,−5,2)=(−6,9,−12,15,−6)

⇒α=−3 [linearly dependent].

We check independence of u1 and u3.

αu1=u3

⇒ α(2,−3,4,−5,2)=(3,−2,7,−9,1)

There is no value of α that satisfies.

⇒ the set {u1,u3} is linearly independent.

We check independence of u1,u3 and u4.

αu1+βu3=u4

⇒ α(2,−3,4,−5,2)+β(3,−2,7,−9,1)=(2,−8,2,−2,6)

⇒(2α+3β,−3α−2β,4α+7β,−5α−9β,2α+β)=(2,−8,2,−2,6)

solving the equations,

⇒ 2α+3β=2,

⇒ −3α−2β=−8,

⇒ 4α+7β=2,

⇒ −5α−9β=−2,

⇒ 2α+β=6

we get,

⇒ α=4,

⇒ β=−2

{u1,u3,u4} is linearly independent.

We check independence of u1,u3 and u5.

αu1+βu3=u5

⇒ α(2,−3,4,−5,2)+β(3,−2,7,−9,1)=(−1,1,2,1,−3)

⇒ (2α+3β,−3α−2β,4α+7β,−5α−9β,2α+β)=(−1,1,2,1,−3)

⇒ 2α+3β=−1,

−3α−2β=1,

4α+7β=2,

−5α−9β=1,

2α+β)=−3

After solving the equations, we don’t have a unique value of α and β.

⇒ the set {u1,u3,u5} is linearly independent.

We check independence of u1,u3,u5 and u6.

αu1+βu2+γu5=u6

⇒α(2,−3,4,−5,2)+β(3,−2,7,−9,1)+γ(−1,1,2,1,−3)=(0,−3,−18,9,12)

⇒2α+3β−γ=0,

−3α−2β+γ=−3,

4α+7β+2γ=−18,

−5α−9β+γ=9,

2α+β−3γ=12

solving the above equations, we get

α=1,

β=−2,

γ=−4

⇒ the set {u1,u3,u5,u6} is linearly independent.

We check independence of u1,u3,u5,u7.

αu1+βu2+γu5=u7

⇒ α(2,−3,4,−5,2)+β(3,−2,7,−9,1)+γ(−1,1,2,1,−3)=(1,0,−2,3,−2)

⇒2α+3β−γ=1,

−3α−2β+γ=0,

4α+7β+2γ=−2,

−5α−9β+γ=3,

2α+β−3γ=−2

After solving the equations, we don’t have a unique value of α,β and γ.

⇒ the set {u1,u3,u5,u7} is linearly independent.

We check independence of u1,u3,u5,u7 and u8.

αu1+βu2+γu5+δu7=u8

⇒α(2,−3,4,−5,2)+β(3,−2,7,−9,1)+γ(−1,1,2,1,−3)+δ(1,0,−2,3,−2)=(2,−1,1,−9,7)

⇒2α+3β−γ+δ=2,

⇒ −3α−2β+γ=−1,

⇒ 4α+7β+2γ−2δ=1,

⇒ −5α−9β+γ+3δ=−9,

⇒ 2α+β−3γ−2δ=7

After solving the equations, we get

⇒ α=−1,

⇒ β=1,

⇒ γ=−2,

⇒ δ=−1

⇒ the set {u1,u3,u5,u7,u8} is linearly independent.

A subset of the set {u1,u2,u3,u4,u5,u6,u7,u8} that forms a basis for W is {u1,u3,u5,u7} or {(2,−3,4,−5,2),(3,−2,7,−9,1),(−1,1,2,1,−3),(1,0,−2,3,−2)}.

Linear Algebra 5th Edition Chapter 1 Page 56 Problem 26 Answer

We are given, u1=(1,1,1,1),

⇒ u2=(0,1,1,1),

⇒ u3=(0,0,1,1) and

u4=(0,0,0,1) from a basis for F4.

We have to find the unique representation of an arbitrary vector {a1,a2,a3,a4} in F4 as a linear combination of u1,u2,u3 and u4.

Let’s assume an arbitrary vector

a=(a1,a2,a3,a4)∈F4

⇒α1u1+α2u2+α3u3+α4u4=a

⇒α1(1,1,1,1)+α2(0,1,1,1)+α3(0,0,1,1)+α4(0,0,0,1)=(a1,a2,a3,a4)

⇒(α1,α1+α2,α1+α2+α3,α1+α2+α3+α4)=(a1,a2,a3,a4)

⇒α1=a1,

α1+α2=a2,α1+α2+α3=a3, α1+α2+α3+α4=a4.

After solving the above set of equations, we get

⇒ α1=a1,

⇒ α2=a2−a1,

⇒ α3=a3−a2,

⇒ α4=a4−a3.

Therefore, the unique representation of

a=(a1,a2,a3,a4) in terms of u1,u2,u3 and u4 is a=a1u1+(a2−a1)u2+(a3−a2)u3+(a4−a3)u4.

Linear Algebra 5th Edition Chapter 1 Vector Spaces

Page 41 Problem 1 Answer

For correct answer

In the problem, the given statement is, “If S is a linearly dependent set, then each vector in S is a linear combination of other vectors in S”.

We need to tell, whether the statement is true or false.We will solve this problem by using definition and properties of vector space.For example, let us take S={(1,0),(2,0),(0,1)}

Taking linear combination of S,

α(1,0)+β(2,0)+γ(0,1)=0

⇒ (α+2β+γ)=(0,0)

⇒ α+2β=0,

⇒  γ=0

If β=t,

for all t∈R

⇒α=−2t,

⇒ β=t,

⇒ γ=0

⇒S is linearly independent set.

If S is linearly dependent, we can assume

α(1,0)+β(2,0)=(0,1)

⇒(α+2β,0)=(0,1)

⇒α+2β=0

0=1

As, “0=1” is not possible, a contradiction.

For all other options of at least one vector.

Read and Learn More Stephen Friedberg Linear Algebra 5th Edition Solutions

In the set, S={(1,0),(2,0),(0,1)}, we can see that (0,1) is not a linear combination of other two vectors (1,0),(2,0).

So, The given statement is not true for every set S

Hence the given statement, “If S is a linearly dependent set, then each vector in S is a linear combination of other vectors in S” is False.

Stephen Friedberg Linear Algebra 5th Edition Solutions For Exercise 1.5 Page 41 Problem 2 Answer

For correct answer

In the problem, the given statement is, “Any set containing the zero vector is linearly dependent”.

We need to tell, whether the statement is true or false.Let us assume a set with zero vector.

⇒ S={0}

Taking linear combination of vectors in S,

⇒ α.0=0

The above, which is true for every α∈R.

For all other options

If a set contains a zero vector, then the set will be linearly dependent.If the set contains zero vector along with any other vector, then we can’t say that it is linearly dependent.

Hence, the given statement, “Any set containing the zero vector is linearly dependent”. is True.

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 3 Answer

For correct answer

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 4 Answer

In the problem, the given statement is, “subsets of linearly dependent sets are linearly dependent”.

We need to tell, whether the statement is true or false.Let us take a set

S={(1,0)(2,0)(0,1)} and assume  C={(1,0)(0,1)} is subset of S.

The linear combination of Vector in S,

α(1,0)+β(2,0)+γ(0,1)=0

⇒(α+2β+γ)=(0,0)

⇒α+2β=0,

⇒ γ=0

Let   B=t

⇒α=−2t,

⇒ β=t,

r=0 for all t∈R.

So, we can say that S is linearly dependent.

The linear combination of vector in C,

α(0,1)+β(0,1)=0

⇒(α,β)=(0,0)

⇒α=0,

⇒ β=0.

These are trivial representations, so C is linearly independent.

It is not possible that all subsets of linearly dependent sets are linearly dependent.

So, the given statement is not true every time.

Hence the given statement, “subsets of linearly dependent sets are linearly dependent”, is False.

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 5 Answer

In the given problem, the statement is, “Subsets of linearly independent sets are linearly independent”.

We need to tell whether the statement is true or false.

Using theorem 1.6 corollary, we can solve this problem.

By theorem 1.6 corollary, we have, if V is a vector space and, then S2 is linearly independent, if S1 is linearly independent.

If a set is not linearly independent, then we cannot say that the subsets of that set are linearly independent.

From the proof of corollary of theorem 1.6, the given statement is true.

Hence, the given statement, “Subsets of linearly independent sets are linearly independent”, is True.

Page 41 Problem 6 Answer

In the given problem, the statement is,

“If a1x1+……..+an

xn=0 and x1,x2………,xn are linearly independent, then all teh scalars ai are zero.

We need to tell whether the statement is true or false.From the definition given in the tip section, we can solve this problem.

If a set {x1,x2,……,xn} is linearly independent, then the coefficient of a linear combination of vectors in that set must be zero.

That is, if a1x1+a2x2……..+anxn=0, all the scalars ai. must be zero, if the set is linearly independent.

If the coefficient of a linear combination of vectors in a set are not equal to zero then we cannot say that the set is linearly independent.

So, it is not always possible that the coefficient of a linear combination of vectors are zero.

Hence, the given statement,

“If a1x1+……..+anxn=0 and x1,x2………,xn are linearly independent, then all the scalars ai are zero” is True.

Chapter 1 Exercise 1.5 Vector Spaces Solved Problems Page 41 Problem 7 Answer

In the question, we are asked to determine that whether the given set {x3+2×2,−x2+3x+1,×3−x2+2x−1} in P3(R) is linearly dependent or linearly independent.

If we can find scalars a1,a2&a3 (not all zero) for a1(x3+2×2)+a2(−x2+3x+1)+a3(x3−x2+2x−1)=0, then the given set is linearly dependent or else it is linearly independent (a1=a2=a3=0).

Consider equation a1(x3+2×2)+a2(−x2+3x+1)+a3(x3−x2+2x−1)=0 ,

By grouping terms we get,

(a1+a3)x3+(2a1−a2−a3)x2+(3a2+2a3)x+(a2−a3)=0

For the polynomial to be zero, the coefficients must be zero

Hence we have equations,

⇒ a1+a3=0

⇒ 2a1−a2−a3=0

⇒ 3a2+2a3=0

⇒ a2−a3=0​

Subtracting equation 3a2+2a3 and 3×(a2−a3=0) ,

We get, a3=0 .

Substituting a3=0 in a1+a3=0 ,

We get a1=0

Substituting a1=0&a3=0  in 2a1−a2−a3=0 ,

We get a2=0

This implies the vector set is linearly independent.

Therefore, the given vector set {x3+2×2,−x2+3x+1,×3−x2+2x−1} in P3(R) is linearly independent.

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 8 Answer

Here, we are asked to determine whether the given set {x3−x,2×2+4,−2×3+3×2+2x+6} in P3(R) is linearly dependent or linearly independent.

If we find scalars a1,a2&a3 (not all zero) for a1(x3−x)+a2(2×2+4)+a3(−2×3+3×2+2x+6)=0 then the given set is linearly dependent or else it is linearly independent (a1=a2=a3=0).

Consider equation a1(x3−x)+a2(2×2+4)+a3(−2×3+3×2+2x+6)=0 ,

By grouping terms we get,(a1−2a3)x3+(2a2+3a3)x2+(−a1+2a3)x+(4a2+6a3)=0

For the polynomial to be zero, the coefficients must be zero

Hence we have equations,

⇒ a1−2a3=0

⇒ 2a2+3a3=0

⇒ −a1+2a3=0

⇒ 4a2+6a3=0​

Consider equation a1−2a3=0 and 2a2+3a3=0 ,

We get, a1=2a3 and a2=−3a3/2 .

So when we pick a3=t ,

We have a1=2t and a2=−3t/2 .

So we got a non-zero solution set for the equation a1(x3−x)+a2(2×2+4)+a3(−2×3+3×2+2x+6)=0 .

This implies the vector set is linearly dependent.

Therefore, the vector set {x3−x,2×2+4,−2×3+3×2+2x+6} in P3(R) is linearly dependent.

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 9 Answer

Here, we are asked to determine whether the set {(1,−1,2),(1,−2,1),(1,1,4)} in R3 is linearly dependent or linearly independent.

If we find scalars a1,a2&a3 (not all zero) for a1(1,−1,2)+a2(1,−2,1)+a3(1,1,4)=0, then the given set is linearly dependent or else it is linearly independent (a1=a2=a3=0).

Consider equation a1(1,−1,2)+a2(1,−2,1)+a3(1,1,4)=0 ,

Multiplying the constants,

​(a1,−a1,2a1)+(a2,−2a2,a2)+(a3,a3,4a3)=0

(a1+a2+a3,−a1−2a2+a3,2a1+a2+4a3)=0

We have equations,

⇒ ​a1+a2+a3=0

⇒ −a1−2a2+a3=0

⇒ 2a1+a2+4a3=0

​Adding equations a1+a2+a3=0 and −a1−2a2+a3=0 ,

We get −a2+2a3=0 .

Adding equations 2×(a1+a2+a3=0) and 2a1+a2+4a3=0 ,

We get −a2+2a3=0 .

This gives a non-zero solution set. Like when a3=t we have a1=−3t and a2=2t .

This implies the vector set is linearly dependent.

Therefore, the vector set {(1,−1,2),(1,−2,1),(1,1,4)} in R3 is linearly dependent.

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 10 Answer

Here, we are asked to determine whether the given set {(1,−1,2),(2,0,1),(−1,2,−1)} in R3 is linearly dependent or linearly independent.

If we find scalars a1,a2&a3 (not all zero) for a1(1,−1,2)+a2(2,0,1)+a3(−1,2,−1)=0, then the given set is linearly dependent or else it is linearly independent (a1=a2=a3=0).

Consider equation a1(1,−1,2)+a2(2,0,1)+a3(−1,2,−1)=0 ,

Multiplying the constants,

(a1,−a1,2a1)+(2a2,0,a2)+(−a3,2a3,−a3)=0(a1+2a2−a3,−a1+2a3,2a1+a2−a3)=0

​We have equations,

⇒ a1+2a2−a3=0−a1+2a3=0

⇒ 2a1+a2−a3=0

​Adding equations a1+2a2−a3=0 and −a1+2a3=0 ,

We get 2a2+a3=0 .

Adding equations −2×(a1+2a2−a3=0) and 2a1+a2−a3=0 ,

We get −3a2+a3=0 .

Adding equations −1×(2a2+a3=0) and −3a2+a3=0 ,

We get a3=0 .

Hence we get a1=a2=a3=0 .

This implies the vector set is linearly independent.

Therefore, the vector set {(1,−1,2),(2,0,1),(−1,2,−1)} in R3 is linearly independent.

Linear Algebra Friedberg Exercise 1.5 Step-By-Step Guide Chapter 1 Page 41 Problem 11 Answer

We are asked to determine whether the set

{x4−x3+5×2−8x+6,−x4+x3−5×2+5x−3,×4+3×2−3x+5,2×4+3×3+4×2−x+1,×3−x+2} in P4(R) is linearly dependent or linearly independent.

So for

a1(x4−x3+5×2−8x+6)+a2(−x4+x3−5×2+5x−3)+a3(x4+3×2−3x+5)+a4(2×4+3×3+4×2−x+1)+a5(x3−x+2)=0

if we find scalars a1,a2,a3,a4&a5 (not all zero) than the given set is linearly dependent or else it is linearly independent (a1=a2=a3=a4=a5=0).

Consider equation

​a1(x4−x3+5×2−8x+6)+a2(−x4+x3−5×2+5x−3)+a3(x4+3×2−3x+5)+a4(2×4+3×3+4×2−x+1)+a5(x3−x+2)=0 ,

By grouping terms we get,

(a1−a2+a3+2a4)x4+(−a1+a2+3a3+a4)x3+(5a1−5a2+3a3+4a4)x2+(−8a1+5a2−3a3−a4−a5)x+(6a1−3a2+5a3+a4+2a5)=0

For the polynomial to be zero, the coefficients must be zero

Hence we have equations,

​a1−a2+a3+2a4=0 −a1+a2+3a3+a4=0

5a1−5a2+3a3+4a4=0

−8a1+5a2−3a3−a4−a5=0

6a1−3a2+5a3+a4+2a5=0​

Now we have four equations and four variables,

solving it we get,

⇒ a1−a2+a3+2a4=0

⇒ −3a2+5a3+15a4−a5=0

⇒ a3+5a4+a5=0

⇒ 4a4+2a5=0

⇒ 5a5=0

we can see that a1=a2=a3=a4=0 is the only solution.

This implies the vector set is linearly independent.

The vector set   in P4(R) is linearly independent.

{x4−x3+5×2−8x+6,−x4+x3−5×2+5x−3,×4+3×2−3x+5,2×4+3×3+4×2−x+1,×3−x+2}

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 12 Answer

Determine whether the set

{x4−x3+5×2−8x+6,−x4+x3−5×2+5x−3,×4+3×2−3x+5,2×4+x3+4×2+8x}  in P4(R) is linearly dependent or linearly independent.

So for  ​

a1(x4−x3+5×2−8x+6)+a2(−x4+x3−5×2+5x−3)+a3(x4+3×2−3x+5)+a4(2×4+x3+4×2+8x)=0

if we find scalars a1,a2,a3&a4 (not all zero) than the given set is linearly dependent or else it is linearly independent (a1=a2=a3=a4=0).

Consider equation

a1(x4−x3+5×2−8x+6)+a2(−x4+x3−5×2+5x−3)+a3(x4+3×2−3x+5)+a4(2×4+x3+4×2+8x)=0 ,

By grouping terms we get,

(a1−a2+a3+2a4)x4+(−a1+a2+a4)x3+(5a1−5a2+3a3+4a4)x2+(−8a1+5a2−3a3+4a4)x+(6a1−3a2+5a3)=0

For the polynomial to be zero, the coefficients must be zero

Hence we have equations,

⇒ a1−a2+a3+2a4=0

⇒ −a1+a2+a4=0

⇒ 5a1−5a2+3a3+4a4=0

⇒ −8a1+5a2−3a3+5a4=0

⇒ 6a1−3a2+5a3=0​

Now we have four equations and four variables,

solving it we get,

⇒ a1−a2−a4=0

⇒ −3a2+9a4=0

⇒ a3+3a4=0

Hence the equation has non-zero solution set,

like when a4=t ,

​a1=4ta2=3ta3=−3t

This implies the vector set is linearly independent.

Therefore, the given vector set

{x4−x3+5×2−8x+6,−x4+x3−5×2+5x−3,×4+3×2−3x+5,2×4+x3+4×2+8x} in P4(R) is linearly independent.

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 13 Answer

Given, Fn in which ej denotes the jth vector whose coordinate is 1 and whose other coordinates are 0.

We have to prove that the given set {e1,e2,…,en} in Fn is linearly independent, where en denote a vector whose nth coordinate is 1 and other coordinates are zero.

Show that the scalars a1,a2,…,an for a1e1+a2e2+…+anen=0 are all zero. then the given set is linearly independent.

First lets write down the vectors of the set,

e1=(1,0,0,0,0,….)

e2=(0,1,0,0,0,….)

.

.

en=(0,0,…,0,0,1)

So the equation a1e1+a2e2+…+anen=0 turns out as,a1(1,0,0,0,0,….)+a2(0,1,0,0,0,….)+…+an(0,0,…,0,0,1)=0

Now lets try to find the solution set of the above equation,

​a1(1,0,0,0,0,….)+a2(0,1,0,0,0,….)+…+an(0,0,…,0,0,1)=0

(a1,0,0,0,0,….)+(0,a2,0,0,0,….)+…+(0,0,…,0,0,an)=0

This implies,

a1=a2,…,an=0

Hence the given set is linearly independent.

Therefore, the given vector set {e1,e2,…,en} in Fn is linearly independent.

Vector spaces Chapter 1 Exercise 1.5 Explained Friedberg Page 41 Problem 14 Answer

Here, we have to prove that the given set S={(1,1,0),(1,0,1),(0,1,1)} in F3 is linearly independent for F=R .

So for F=R , if we show that the scalars for a1(1,1,0)+a2(1,0,1)+a3(0,1,1)=0 are all zero (a1

=a2=a3=0) , then the given set is linearly independent.

Consider equation a1(1,1,0)+a2(1,0,1)+a3(0,1,1)=0 ,

Multiplying the constants,

​(a1,a1,0)+(a2,0,a2)+(0,a3,a3)=0(a1+a2,a1+a3,a2+a3)=0

​We have equations,

​⇒ a1+a2=0

⇒ a1+a3=0

⇒ a2+a3=0​

Adding equations −1×(a1+a2=0) and a1+a3=0 ,

We get −a2+a3=0 .

Adding equations −a2+a3=0 and a2+a3=0 ,

We get a3=0 .

This implies a1=a2=a3=0 .

Hence the vector set is linearly independent.

Therefore, the given vector  set S={(1,1,0),(1,0,1),(0,1,1)} in F3 for F=R is linearly independent.

Friedberg 5th Edition Chapter 1 Exercise 1.5 Examples Page 42 Problem 15 Answer

Here, we have to prove that the given set S={(1,1,0),(1,0,1),(0,1,1)} in F3 is linearly dependent if F has characteristic 2.

Since F is a field with characteristic 2 we have 1+1=0 .

Therefore we consider the linear combination of the vectors of S where scalars belong to F .

So we have the equation,

⇒ a1(1,1,0)+a2(1,0,1)+a3(0,1,1)=0

Let us try a1=a2=a3=1 ,

​=(1,1,0)+(1,0,1)+(0,1,1)

=(1+1,1+1,1+1)

=(0,0,0)​

So we found that  a1=a2=a3=1 is a solution of equation a1

⇒ (1,1,0)+a2

⇒ (1,0,1)+a3

⇒ (0,1,1)=0

Hence it is a finite linear combination of vectors of S whose coefficients are not all equals to 0.

Hence the vector set is linearly dependent.

Hence it is proved that the given vector set S={(1,1,0),(1,0,1),(0,1,1)} in F3 is linearly dependent if F has characteristic 2.

Page 42 Problem 16 Answer

Given in the question, u,v as distinct vectors in a vector space V.

We have to show that {u,v} is linearly dependent if and only if u or v is a multiple of each other.

Let {u,v} be linearly dependent such that αu+βv=0 where α,β≠0 and α,β∈R

αu+βv=0

αu=−βv

u=−βv

α ..u is a multiple of v

Let u be the multiple of v, such that u=λv, λ∈R

u−λv=0

u×1+(−λ)v=0 ..{u,v} is linearly dependent.

Therefore,{u,v} is linearly dependent if and only if u or v is a multiple of each other.

Linear Algebra 5th Edition Chapter 1 Page 41 Problem 17 Answer

The question asks to give an example of three linearly dependent vectors in R3 such that none of them is multiple of another.

Consider three different vectors v1,v2,v3 and then we would further check for their linear dependency.

Considering vectors v1,v2,v3 which are not multiples of another.

Let,​v1=(1,0,0)

⇒ v2=(0,1,1)

⇒ v3=(1,1,1)​

Considering

⇒ v1=αv2

⇒ (1,0,0)=α(0,1,1)

⇒ α=0

Considering

⇒ v2=βv3

⇒ (0,1,1)=β(1,1,1)

⇒ β=0,1

Considering

⇒ v3=γv1

⇒ (1,1,1)=γ(1,0,0)

⇒ γ=1

To show that v1,v2,v3 is linearly dependent,

⇒ αv1+βv2+γv3=0

⇒ α(1,0,0)+β(0,1,1)+γ(1,1,1)=(0,0,0)

⇒ (α,0,0)+(0,β,β)+(γ,γ,γ)=(0,0,0)

So,α+γ=0

⇒ β+γ=0

⇒ β+γ=0

⇒ α,β=−a

⇒ γ=a,∀a∈R

Therefore,{(1,0,0),(0,1,1),(1,1,1)} are three linearly dependent vectors in R3 such that none of them is multiple of another.

Linear Algebra 5th Edition Chapter 1 Vector Spaces

Page 33 Problem 1 Answer

Here we have to state whether the statement “The zero vector is a linear combination of any nonempty set of vectors” is true or false.

Zero vector will be a unique vector of length zero. It can be represented as 0=0v1+0v2….+0vn.

From the above definition, we can say that a zero vector will be a linear combination of any set of vectors, empty or not.

Therefore, the given statement will be true.

An empty sum, which means, the sum of no vectors, will be usually defined to be zero.

Therefore, the given statement is justified and cannot be false.

The given statement “The zero vector is a linear combination of any nonempty set of vectors” is true.

Stephen Friedberg Linear Algebra 5th Edition Solutions For Exercise 1.4 Linear Algebra 5th Edition Chapter 1 Page 33 Problem 2 Answer

Here we have to state whether the statement “The span of ϕ is ϕ ” is true or false.

The span of a set of vectors will be the smallest vector space that includes all of them.

An empty set, that is, the smallest vector space will include the zero vector.

From the above explanation, we can say that an empty set contains the zero vector, so it is not empty in essence.

Therefore, the given statement is false.

An empty set will be the one which only contains the zero vector.

If the only component of ϕ will be the zero vector, it becomes a non-zero set.

Therefore, the given statement cannot be true.

The statement given is, “The span of ϕ is ϕ ” is false.

Read and Learn More Stephen Friedberg Linear Algebra 5th Edition Solutions

Linear Algebra 5th Edition Chapter 1 Page 33 Problem 3 Answer

We have to state whether the statement “If S is a subset of a vector space V, then span ( S ) equals the intersection of all subspaces of V that contain S ” is true or false.

The span of S includes all the vectors in that set, which in turn is a subset of V .

Therefore, the span of V already contains all those vectors that appear in S .

From the above explanation, we can say that the span ( S ) which will be equal to the intersection of all subspaces of V that contain S .

Therefore, the given statement will be true.

As S is a subset of  V , all its vectors are derived from it.

Therefore, any vector appearing in S is by default, a part of V .

So the span of S intersects the part of the span of V that includes all vectors of S .

Hence, the statement given is justified and cannot be false.

The statement “If S is a subset of a vector space V, then span ( S ) equals the intersection of all subspaces of V that contain S ” is true.

Linear Algebra 5th Edition Chapter 1 Page 33 Problem 4 Answer

We have to state whether the statement “In solving a system of linear equations, it is permissible to multiply an equation by any constant” is true or false.

The statement “In solving a system of linear equations, it is permissible to multiply an equation by any constant” will not false.

Linear Algebra 5th Edition Chapter 1 Page 33 Problem 5 Answer

Here we have to state whether the statement “In solving a system of linear equations, it is permissible to add any multiple of one equation to another” is true or false.

Here add any multiple of one equation to the other, it is permissible.

Adding an arbitrary multiple of an equation to another equation will be still yielding an equivalent system.

Therefore, the given statement is true.

When solving a system of linear equations, it is permissible to add any multiple of one equation to another.

It is mathematically permissible to perform these operations on a system of linear equations.

However, the only exception is that you cannot multiply an equation with its multiplicative inverse, as it will vary the value of the equation.

Therefore, the statement cannot be false.

The statement “In solving a system of linear equations, it is permissible to add any multiple of one equation to another” is true.

Chapter 1 Exercise 1.4 Vector Spaces Problem Set Page 33 Problem 6 Answer

Here we have to state whether the statement “Every system of linear equations has a solution” is true or false.

All systems of linear equation may not necessarily have a solution, they might be inconsistent also.

Only homogeneous equations have solutions, one of which will be always the zero vector.

From the explanation given above, we can say that it is not necessary for every system of equations to have a solution.

Therefore, the given statement is false.

Some non-homogeneous systems of linear equations will be existing.

If and only if its determinant is non-zero, these equations have a unique solution.

When its determinant will be zero, they do not have any solution.

Therefore we can say that every system of linear equations may not have a solution.

The given statement “Every system of linear equations has a solution” is false.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 7 Answer

Given: x3−3x+5,×3+2×2−x+1,×3+3×2−1

We need to determine whether the first polynomial can be expressed as a linear combination of the other two.

Make use of the definition of linear combination for solving the given question.

Assume a and b are scalar, then find a and b such that.

⇒ x3−3x+5=a(x3+2×2−x+1)+b(x3+3×2−1)

=(a+b)x3+(2a+3b)x2+(−a)x+(a−b)       ..(1)

Thus we are led to the following system of linear equations:

​⇒ a+b=1

⇒ 2a+3b=0

⇒ −a=−3

⇒ a−b=5

From the equation −a=−3, we find that,a=3.

Adding equations to the others in order to eliminate  a, we find that

⇒ ​a+b−a=1−3

⇒ b=−2

Put values of a and b in the equation (1), we find that​

(a+b)x3+(2a+3b)x2+(−a)x+(a−b)=(3+(−2))x3+(2(3)+3(−2))x2+(−3)x+(3−(−2)) =x3−3x+5

Hence   x3−3x+5=3(x3+2×2−x+1)−2(x3+3×2−1) .

The first polynomial  x3−3x+5 is the linear combination of  x3+2×2−x+1  and x3+3×2−1.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 8 Answer

Given: 4×3+2×2−6,×3−2×2+4x+1,3×3−6×2+x+4

We need to determine whether the first polynomial can be expressed as a linear combination of the other two.

Use the definition of linear combination to solve the given question.

Let a and b are scalar, then find a and b such that.

4×3+2×2−6=a(x3−2×2+4x+1)+b(3×3−6×2+x+4)

=(a+3b)x3+(−2a−6b)x2+(4a+b)x+(a+4b)       ..(1)

Thus we are led to the following system of linear equations:

⇒ ​a+3b=4

⇒ −2a−6b=2

⇒ 4a+b=0

⇒ a+4b=−6

​Adding equations to the others in order to eliminate  a, we find that

⇒ ​a+3b+a+4b−2a−6b=4−6+2

⇒ b=0

Again,  substitute value of b  in any of the equation and solve for a.

⇒ ​a+3(0)=4

⇒ a=4

Put values of a and b in the equation (1), we find that

(a+3b)x3+(−2a−6b)x2+(4a+b)x+(a+4b)=((4)+3(0))x3+(−2(4)−6(0))x2+(4(4)+0)x+(4+4(0)) =4×3−8×2+16x+4

Hence

4×3+2×2−6≠4(x3−2×2+4x+1)+0(3×3−6×2+x+4)

The first polynomial  4×3+2×2−6 is not the linear combination of  x3−2×2+4x+1  and 3×3−6×2+x+4.

Friedberg Chapter 1 Exercise 1.4 Vector Spaces Explanation Page 34 Problem 9 Answer

Given: −2×3−11×2+3x+2,×3−2×2+3x−1,2×3+x2+3x−2 We need to determine whether the first polynomial can be expressed as a linear combination of the other two.

Make use of linear combination for solving the given question.

Assume a and b are scalar, then calculate a and b such that.

−2×3−11×2+3x+2=a(x3−2×2+3x−1)+b(2×3+x2+3x−2)

=(a+2b)x3+(−2a+b)x2+(3a+3b)x+(−a−2b)       ..(1)

Thus we are led to the following system of linear equations:

⇒ ​a+2b=−2

⇒ −2a+b=−11

⇒ 3a+3b=3

⇒ −a−2b=2​

Adding equations to the others in order to eliminate  a, we find that

​−a−2b−2a+b+3a+3b=2−11+3

⇒ 2 b=6

⇒ 3 b=3

​Again,  substitute value of b  in any of the equation and solve for a .

⇒ ​a+2(3)=−2

⇒ a=−8

​Put values of a and b in the equation (1), we find that

(a+2b)x3+(−2a+b)x2+(3a+3b)x+(−a−2b)=(−8+2(3))x3+(−2(−8)+3)x2+(3(−8)+3(3))x+(−(−8)−2(3))

=−2×3+16×2−15x+2

​Hence   −2×3−11×2+3x+2≠−8(x3−2×2+3x−1)+3(2×3+x2+3x−2) .

Hence, the first polynomial  −2×3−11×2+3x+2 is not the linear combination of  x3−2×2+3x−1  and  2×3+x2+3x−2.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 10 Answer

Here, x3+x2+2x+13,2×3−3×2+4x+1,×3−x2+2x+3 is given a

We have to find whether the first polynomial can be expressed as a linear combination of the other two

Make use of the definition of linear combination to solve the given question.

Let a and b are scalar, then find a and b such that.

x3+x2+2x+13=a(2×3−3×2+4x+1)+b(x3−x2+2x+3)

=(2a+b)x3+(−3a−b)x2+(4a+2b)x+(a+3b)       ..(1)

Thus we are led to the following system of linear equations:

⇒ ​ 2a+b=1

⇒ −3a−b=1

⇒ 4a+2b=2

⇒ a+3b=13

​Adding equations to the others in order to eliminate  a, we find that

​2a+b+a+3b−3a−b=1+13+1

⇒ 3 b=15

⇒ b=5

​Again,  substitute value of b  in any of the equation and solve for a.

​⇒ 2a+5=1

⇒ a=−2

Put values of a and b in the equation (1), we find that​

x3+x2+2x+13=(2a+b)x3+(−3a−b)x2+(4a+2b)x+(a+3b) =(2(−2)+5)x3+(−3(−2)−5)x2+(4(−2)+2(5))x+(−2+3(5)) =x3+x2+2x+13

Hence   x3+x2+2x+13=−2(2×3−3×2+4x+1)+5(x3−x2+2x+3) .

Hence , the first polynomial  x3+x2+2x+13 is  the  linear combination of  2×3−3×2+4x+1  and  x3−x2+2x+3 .

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 11 Answer

Here, x3−8×2+4x,x3−2×2+3x−1,×3−2x+3 is given We have to determine whether the first polynomial can be expressed as a linear combination of the other two.

Make use of the definition of linear combination to solve the given question.

Assume a and b are scalar, then find a and b such that.

x3−8×2+4x=a(x3−2×2+3x−1)+b(x3−2x+3)

=(a+b)x3+(2a+2b)x2+(3a)x+(−a+3b)       ..(1)

Thus we are led to the following system of linear equations:

⇒ ​ a+b=1

⇒ 2a+2b=−8

⇒ 3a=4

⇒ −a+3b=0​

Adding equations to the others in order to eliminate  a, we find that

​a+b−a+3b=1+0

4b=1

b=1/4

Again,  substitute value of b  in any of the equation and solve for a.

​a+1/4=1

a=1−1/3

a=2/3

Put values of a and b in the equation (1), we find that​

(a+b)x3+(2a+2b)x2+(3a)x+(−a+3b)=((2/3)+(1/4))x3+(2(2/3)+2(1/4))x2+3(2/3)x+(−(2/3)+3(1/4))

=11/12×3+11/6×2+2x+1/12

Hence   x3−8×2+4x≠2/3(x3−2×2+3x−1)+1/4(x3−2x+3) .

Hence, the first polynomial  x3−8×2+4x is not the linear combination of  x3−2×2+3x−1  and  x3−2x+3.

Understanding Exercise 1.4 In Friedberg Linear Algebra Chapter 1 Page 34 Problem 12 Answer

Here, 6×3−3×2+x+2,×3−x2+2x+3,2×3−3x+1 is given We have to calculate whether the first polynomial can be expressed as a linear combination of the other two.

Make use of the definition of linear combination to solve the given question.

Let a and b are scalar, then find a and b such that.

6×3−3×2+x+2=a(x3−x2+2x+3)+b(2×3−3x+1)

=(a+2b)x3+(−a)x2+(2a−3b)x+(3a+b)       ..(1)

Thus we are led to the following system of linear equations:

​ ⇒ a+2b=6

⇒ −a=−3

⇒ 2a−3b=1

⇒ 3a+b=2

From the above  equation −a=−3 , we find that ,a=3

Adding equations to the others in order to eliminate  a, we find that

​⇒ a+2b−a=6−3

⇒ 2b=3

⇒ b=3/2

Put values of a and b in the equation (1), we find that​

(a+2b)x3+(−a)x2+(2a−3b)x+(3a+b)=(3+2(3/2))x3+(−3)x2+(2(3)−3(3/2))x+(3(3)+3/2)

=6×3−3×2+3/2x+21/2

Hence   6×3−3×2+x+2=3(x3−x2+2x+3)+3/2(2×3−3x+1) .

Hence, the first polynomial  6×3−3×2+x+2 is not the linear combination of  x3−x2+2x+3  and  2×3−3x+1.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 13 Answer

Here,  (2,−1,1),S={(1,0,2),(−1,1,1)} is given We have to calculate whether the given vector is in the span of S.

Check whether the given vector can be shown as a linear combination of vectors in  S

to solve the given question.

Check whether the given vector can be shown as a linear combination of vectors in  S .

Let  a and b are scalars .

⇒ ​(2,−1,1)=a(1,0,2)+b(−1,1,1)

⇒ (2,−1,1)=(a,0,2a)+(−b,b,b)

⇒ (2,−1,1)=(a−b,b,2a+b) ……(1)

⇒ ​ a−b=2

⇒ b=−1

⇒ 2a+b=1​

Add equation first and second to eliminate b.

⇒ ​a−b+b=2−1

⇒ a=1

Substitute value of  b in first equation, we get

​⇒ 1−b=2

⇒ b=−1

Substitute values of a and b in the equation  (1), we get​

⇒ (2,−1,1)=(a−b,b,2a+b)

=(1−(−1),−1,2(1)−1)

=(2,−1,1)​

Hence, vector (2,−1,1) can be expressed as a linear combination of (1,0,2) and (−1,1,1), so that  (2,−1,1) is in the span of S.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 14 Answer

Given: (−1,2,1), S={(1,0,2),(−1,1,1)} is given and we have to determine whether the given vector is in the span of S.

We have to verify whether the given vector can be represented as a linear combination of vectors in  S to solve the given question.

Verify whether the given vector can be shown as a linear combination of vectors in  S.

Let  a and b are scalars .

​(−1,2,1)=a(1,0,2)+b(−1,1,1)

(−1,2,1)=(a,0,2a)+(−b,b,b)

(−1,2,1)=(a−b,b,2a+b) ……(1)

​ ⇒ a−b=−1

⇒ b=2

⇒ 2a+b=1​

Add equation first and second to eliminate b.

⇒ ​a−b+b=−1+2

⇒ a=1

Substitute value of  b in first equation , we get

⇒ ​1−b=−1

⇒ b=2

Substitute values of a and b in the equation  (1), we get

​⇒ (a−b,b,2a+b)=(1−2,2,2(1)+2)

=(−1,2,4)

​Hence,vector (−1,2,1) can not be expressed as a linear combination of (1,0,2) and (−1,1,1) , so that  (2,−1,1) is not in the span of S.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 15 Answer

Given:  (−1,1,1,2), S={(1,0,1,−1),(0,1,1,1)} is given and we have to determine whether the given vector is in the span of S.

We have to check whether the given vector can be shown as a linear combination of vectors in S for solving the given question.

Analyse  whether the given vector can be shown as a linear combination of vectors in  S.

Let  a and b are scalars .

(−1,1,1,2)=a(1,0,1,−1)+b(0,1,1,1)

(−1,1,1,2)=(a,0,a,−a)+(0,b,b,b)

(−1,1,1,2)=(a,b,a+b,−a+b) ……(1)

​⇒  a=−1

⇒ b=1

⇒ a+b=1

⇒ −a+b=2

Apply results from the first two equations to the other two, we get

⇒ ​ a=−1

⇒ b=1

⇒ 0≠1

⇒ 2=2

​Hence,vector (−1,1,1,2) can not be expressed as a linear combination of (1,0,1,−1) and (0,1,1,1), so that  (−1,1,1,2) is not in the span of S.

Exercise 1.4 Notes From Friedberg Linear Algebra 5th Edition Chapter 1 Page 34 Problem 16 Answer

Given,  (2,−1,1,−3), S={(1,0,1,−1),(0,1,1,1)} is given and we have to calculate whether the given vector is in the span of S.

Verify whether the given vector can be shown as a linear combination of vectors in  Sto solve the given question.

Verify whether the given vector can be shown as a linear combination of vectors in  S.

Let  a and b are scalars .

(2,−1,1,−3)=a(1,0,1,−1)+b(0,1,1,1)

(2,−1,1,−3)=(a,0,a,−a)+(0,b,b,b)

(2,−1,1,−3)=(a,b,a+b,−a+b) ……(1)

That is​

⇒ a=2

⇒ b=−1

⇒ a+b=1

⇒ −a+b=−3

​Apply results from the first two equations to the other two, we get

​ ⇒ a=2

⇒ b=−1

⇒ 1=1

⇒ −3=−3

​Hence,vector (2,−1,1,−3) can be expressed as a linear combination of (1,0,1,−1) and (0,1,1,1), so that  (2,−1,1,−3) is in the span of S.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 17 Answer

Given,  −x3+2×2+3x+3,S={x3+x2+x+1,×2+x+1,x+1} is given and we have to determine whether the given vector is in the span of S.

Verify whether the given vector can be represented vas a linear combination of vectors in  Sto solve the given question.

Check whether the given vector can be shown as a linear combination of vectors in  S.

Let  a,b and c are scalars .

−x3+2×2+3x+3=a(x3+x2+x+1)+b(x2+x+1)+c(x+1)−x3+2×2+3x+3=(ax3+ax2+ax+a)+(bx2+bx+b)+(cx+c)

−x3+2×2+3x+3=ax3+(a+b)x2+(a+b+c)x+a+b+c ……(1)

Compare  like terms of above equation , we get

⇒ ​ a=−1

⇒ a+b=2

⇒ a+b+c=3

⇒ a+b+c=3​

Subtract  equation second to the first to eliminate a.

⇒ a+b−a=2−(−1)

⇒ b=3

Substitute value of  b in second equation, we get

​⇒ a+3=2

⇒ a=−1

Substitute value of   a and b in third equation, we get​

⇒ −1+3+c=3

⇒ c=1

​Substitute values of a,b and c in the equation  (1), we get

ax3+(a+b)x2+(a+b+c)x+a+b+c=2×3+2×2+3x−1+3+1 =2×3+2×2+3x+3

​Hence,vector x3+2×2+3x+3 can be expressed as a linear combination of x3+x2+x+1, x2+x+1 and x+1, so that  x3+2×2+3x+3 is in the span of S.

Linear Algebra 5th Edition Chapter 1 Page 34 Problem 18 Answer

Given:  2×3−x2+x+3,S={x3+x2+x+1,×2+x+1,x+1} is given and we have to determine whether the given vector is in the span of S.

Verify whether the given vector can be shown as a linear combination of vector in S to solve the given question.

Check  whether the given vector can be shown as a linear combination of vector in  S.

Let  a,b and c are scalars .​

2×3−x2+x+3=a(x3+x2+x+1)+b(x2+x+1)+c(x+1)2×3−x2+x+3=(ax3+ax2+ax+a)+(bx2+bx+b)+(cx+c)

2×3−x2+x+3=ax3+(a+b)x2+(a+b+c)x+a+b+c ……(1)

​Compare  like terms of above equation , we get

​ ⇒ a=2

⇒ a+b=−1

⇒ a+b+c=1

⇒ a+b+c=3​

Substitute a in the  second equation , we get

⇒ ​2+b=−1

⇒ b=−3

Substitute value of   a and b in third equation, we get

⇒ ​2−3+c=1

⇒ c=2

Substitute values of a,b and c in the equation  (1), we get

​ax3+(a+b)x2+(a+b+c)x+a+b+c=2×3+x2+x+2−3+2 =2×3+x2+x+1

​Hence ,vector  2×3−x2+x+3  can  not be expressed as a linear combination  of x3+x2+x+1 , x2+x+1 and x+1 , so that  2×3−x2+x+3 is not   in the span of S .

Friedberg 5th Edition Exercise 1.4 Guide For Vector Spaces Chapter 1 Page 35 Problem 19 Answer

Given,Fn in which ej denote the vector whose jth coordinate is 1 and whose other coordinates are 0.

We have to prove that  {e1,e2,…….en}  generates  Fn.

Find whether the given vector can be shown as a linear combination of vectors in  Fn for solving the question.

Using  statement  given in the question, ej denote the vector whose jth coordinate is 1 and whose other coordinates are  0,  we get

⇒ ​e1=(1,0,…………,0)

⇒ e2=(0,1,…………,0) .

.

.

.

⇒ en=(0,0,………….,1)

​Let us take an arbitrary vector  (h1,h2,…………hn)   in  Fn is a linear combination of the given vectors and scalars  (a1,a2,……….,an).

⇒ (h1,h2,……….,hn)=a1

⇒ (1,0,….,0)+a2

⇒ (0,1,…..,0)+……+an

⇒ (0,0,….,1)

=(a1,0,….,0)+(0,a2,…..,0)+……+(0,0,….,an)

=(a1,a2,……,an)​h1

=a1h2

=a2

.

.

hn=an

Hence  (h1,h2,…………hn) can be expressed as a linear combination of {e1,e2,…….en}  and {e1,e2,…….en} generates  Fn .

Hence proved that  {e1,e2,…….en}  generates  Fn,where in  Fn, ej denote the vector whose jth coordinate is 1 and whose other coordinates are 0.

Linear Algebra 5th Edition Chapter 1 Page 35 Problem 20 Answer

Given: A set {1,x,x2,−−−,xn}Pn(F) is generated by {1,x,x2,−−−,xn}.To find: We need to show that Pn

(F) is generated by {1,x,x2,−−−,xn}.Let us assume a linear combination that belongs to Pn(F)

and then prove that Pn(F) is generated by {1,x,x2,−−−,xn}.

To prove that {1,x,x2,−−−,xn} generated Pn(F), we need to show that an arbitrary polynomial in Pn(F)

is a linear combination of the polynomials in set.

So, let us assume, P(x)=a0+a1x+−−−+anxn∈Pn(F) and scalars α0,α1,−−−,αn∈F

As α0,α1,−−−,αn∈F, we can write the linear combination of P(x) in terms of α0,α1,−−−,αn

as,P(x)=a0+a1x+α2×2+−−−+anxn

From Step 1 P(x)=a0+a1x+a2x2+−−−+anxn

So, a0+a1x+a2x2+−−−+anxn=α0+α1x+−−−+αnxn

On comparing the coefficients of 1,x,x2,−−−,xn

a0=α0

⇒ a1=α1

⇒ a2=α2

⋅

⋅

⋅

⇒ an=αn

⇒P(x)=a0.1+a1x+−−−+anxn is true.So, Pn(F) is generated by {1,x,−−−,xn}

Hence showed that Pn(F) is generated by {1,x,−−−,xn}.

Linear Algebra 5th Edition Chapter 1 Vector Spaces Page 20 Problem 1 Answer

Given: V is a vector space and W is a subset of V.

To find: whether the given statement is true or false.

The fields that V and W are vector spaces over are not specified. Those fields need to be equal for the statement to be true.

Assume V=R and W=Q. As W is not a vector space over R , it is not a subspace of V . Therefore, it is false.

Given: V is a vector space and W is a subset of V.

To find: whether the given statement is true or false.

The statement to be true, W must be a vector space over R . But it is not so.

Therefore, the given statement is false as W is not a vector space over R

Read and Learn More Stephen Friedberg Linear Algebra 5th Edition Solutions.

Stephen Friedberg Linear Algebra 5th Edition Solutions For Exercise 1.3 Chapter 1 Page 20 Problem 2 Answer

The given statement is “The empty set is a subspace of every vector space.”

We need to find whether the given statement is true or false.

Let V be any vector space.

According to theorem 1.3, ϕ is a subspace of V if and only if:

⇒ 0∈ϕ

⇒ ∀x,y∈ϕx+y∈ϕ

⇒ ∀c∈F,∀x∈ϕc×xϕ

Since, 0∈ϕ, it is false.

The given statement is “The empty set is a subspace of every vector space.”

We need to tell whether the given statement is true or false.

The statement to be true, the relationship must be 0∉ϕ but it is not so. Thus, it is not true.

Hence, the given statement is false as 0∈ϕ.

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 3 Answer

Given:  “If V is a vector space other than the zero-vector space, then V contains a subspace W such that W≠V .”

To find: whether the given statement is true or false.

When V is not the zero-vector space then the zero-vector space is a subspace and we have to prove this statement.

{0} is a subspace of every V and V≠{0} , Therefore it is true.

Given that “If V is a vector space other than the zero-vector space, then V contains a subspace W such that W≠V .”

We have to calculate whether the given statement is true or false.

For the statement to be false, we need to show that {0} is not a subspace of every V . But it is not possible.

Therefore the statement given will be true as {0} is a subspace of every V and V≠{0} .

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 4 Answer

The given statement is “The intersection of any two subsets of V is a subspace of V .”

Given: “The intersection of any two subsets of V is a subspace of V .”

To calculate whether the given statement is true or false.

Let V=R ,

⇒ W1={0,1} and W2={1} .

For the statement to be true, we need to represent that 0∉W1∩W2, but we can’t do it. Hence, it is not true.

Therefore, the given statement will be false as 0∈W1∩W2 .

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 5 Answer

Given: “An n×n diagonal matrix can never have more than n nonzero entries.”

To calculate: whether the given statement is true or false.

n×n diagonal matrix has n entries on its diagonal which means it can have less or equal to n non-zero entries. Therefore, the statement is true.

Given: “An n×n diagonal matrix can never have more than n nonzero entries.”

To find whether the given statement is true or false.

For the statement to be false, n×n diagonal matrix has n entries on its diagonal which means it can have more than n non-zero entries, which is not true for a diagonal matrix.

Therefore, the given statement is true as the n×n diagonal matrix has n entries on its diagonal which means it can have less or equal to n non-zero entries.

Chapter 1 Exercise 1.3 Vector Spaces Solved Examples 

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 6 Answer

The given statement is “The trace of a square matrix is the product of its diagonal entries.”

We need to find whether the given statement is true or false.

From the tip section, we know that the trace is the sum of the diagonal entries of a square matrix.

Hence, it is false.

The given statement is “The trace of a square matrix is the product of its diagonal entries.”

We need to find whether the given statement is true or false.

For the statement to be true we need to show that the trace of a square matrix is the product of its diagonal entries which is not true.

Hence, the given statement “The trace of a square matrix is the product of its diagonal entries” is false as trace is the sum of the diagonal entries of a square matrix.

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 7 Answer

The given statement is “Let W be the xy− plane R3; that is, W={(a1,a2,0):a1,a2∈R} Then W=R2 .”

We need to find whether the given statement is true or false.

W has elements with 3 coordinates whereas R2 has elements with 2 coordinates so they cannot be the same. Hence it is false.

The given statement is “Let W be the xy− plane R3 ; that is, W={(a1,a2,0):a1,a2∈R} Then W=R2 .”

We need to find whether the given statement is true or false.

For the statement to be true, we need to show that W=R2

but it is not possible as W has elements with 3 coordinates whereas R2 has elements with 2 coordinates.

Hence, the given statement “Let W be the xy− plane R3 ; that is W={(a1,a2,0):a1,a2∈R}

Then W=R2 ” is false as W has element with 3 coordinates whereas R2 has elements with 2 coordinates.

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 8 Answer

We have to prove that (aA+bB)t=aAt+bBt.

We will use the properties of transpose to prove the given results.

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 9 Answer

It is required to prove that (AT)T=A.

Make use the properties of transpose to prove the given results.

From the above explanation, it is proved that (AT)T=A.

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 10 Answer

It is required to prove that A+AT is a symmetric matrix.

At first take the transpose of A+AT and then check whether it is similar to the matrix or not.

In order to show that A+AT, we need to prove that.

⇒ (A+AT)T=A+AT

Taking transpose of A+AT, we get:

⇒ (A+AT)T.

Using (a+b)T=aT+bT , we get:

⇒ (A+AT)T=AT+(AT)T

Using (AT)T=A

⇒ AT+(AT)T=AT+A .

We know that the addition of the matrix is commutative, so,

⇒ (A+AT)T=A+AT .

Hence, A+AT is a symmetric matrix.

From the above explanation, A+AT is a symmetric matrix.

Friedberg Chapter 1 Vector Spaces Exercise 1.3 Explanation Page 20 Problem 11 Answer

It is required to prove that tr(aA+bB)=atr(A)+btr(B).

Make use of the formula for the trace of a square matrix as mentioned is the tip section.

Let A,B∈Mn×n(F) and a,b∈F.

⇒ tr(aA+bB)=i=1

⇒ ∑n(aAii+bBii)tr(aA+bB)=i=1

⇒ ∑naAii+i=1

⇒ ∑nbBii

Further calculating, we get:

⇒ tr(aA+bB)=ai=1

⇒ ∑nAii+bi=1

⇒ ∑nBii

⇒ tr(aA+bB)=atr(A)+btr(B)

​From the above explanation, we proved tr(aA+bB)=atr(A)+btr(B).

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 12 Answer

It is required to prove that diagonal matrices are symmetric matrices.

Make use of the properties of diagonal and symmetric matrices.

Let A∈Mn×n(F) such that

⇒ A={​aij

⇒ i = j

⇒ 0 i≠j​}

A is symmetric if AT=A .

⇒ AT = AT(ij )

⇒ A = ATji

⇒ AT = {aji j = i

⇒ 0 j ≠ i}

⇒ AT = A

From the above explanation, we proved that diagonal matrices are symmetric matrices.

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 13 Answer

The set, W1={(a1,a2,a3)∈R3:a1=3a2 and a3=−a2} has been given.

We have to determine whether the set is the subspace of R3 under the operations of addition and scalar multiplication defined on R3.

We can let a2=a.

We will verify for addition and multiplication both.

To check for 0,

As we know that, 0∈R , so

⇒ 0R​3=(0,0,0)

⇒ 0R​3=(3⋅0,0,−0)∈W1

Therefore, W1 isn’t empty.

Now, let a,b∈R, so

⇒ (a,b)R​3=(3a,a,−a)+(3b,b,−b)

⇒ (a,b)R​3=a(3,1,−1)+b(3,1,−1)

⇒ (a,b)R​3=(a+b)⋅(3,1,−1)

⇒ (a,b)R​3=(3⋅(a+b),(a+b),−a−b)

As the distributive property is applicable for vectors in R3

⇒ (3a,a,−a)+(3b,b,−b)=(3⋅(a+b),(a+b),−a−b)

This shows that,for all x,y∈W1

⇒ x+y∈W1

It is closed under addition.

Now, let a,b∈R, so

(a,b)R​3=b⋅(3a,a,−a)

(a,b)R​3=(3(ba),ba,−ba)

This shows that,b⋅x∈W1∀x∈W1,∀b∈R

It is closed under scalar multiplication.

As, W1 is a subset of R3 and it satisfies all the conditions of vector space.

The set W1={(a1,a2,a3)∈R3:a1=3a2 and a3=−a2} is a subspace of R3.

Linear Algebra 5th Edition Chapter 1 Page 20 Problem 14 Answer

The set,

We have to find whether the set is the subspace of R3

under the operations of addition and scalar multiplication defined onR3 .

We will verify for addition and multiplication both.

The given matrix is not a square matrix, that’s why we can’t compute its trace.

Understanding Exercise 1.3 in Friedberg Linear Algebra 5th Edition Chapter 1 Page 20 Problem 15 Answer

The set, W2={(a1,a2,a3)∈R3:a1=a3+2} is given.

We have to find whether the set is the subspace of R3 under the operations of addition and scalar multiplication defined on R3.

We will verify for addition and multiplication both.

We have,W2={(a1,a2,a3)∈R3:a1=a3+2}

{(a1,a2,a3)∈R3:a1=a3+2}={(b+2,a,b)∣∈R3}

Now,(2,0,0)∈W2

Therefore, W2 isn’t empty.

Now, let (a,b),(c,d)∈R , so((a,b),(c,d))R​3

=(b+2,a,b),(d+2,c,d)∈W2

⇒ (b+2,a,b),(d+2,c,d)=((d+b)+4,a+c,b+d)

But, (d+b)+4 is not of the form of a1=a3+2 .

Therefore, ((d+b)+4,a+c,b+d)∉W2

⇒ (a,b)R​3=(3⋅(a+b),(a+b),−a−b)

So, W2 is not closed under addition.

As, W2 is not closed under addition.

The set W2={(a1,a2,a3)∈R3:a1=a3+2} is not a subspace of R3 .

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 16 Answer

The set, W3={(a1,a2,a3)∈R3:2a1−7a2+a3=0} has been given .

To find if the set is the subspace of R3 under the operations of addition and scalar multiplication explained on R3.

We will verify for addition and multiplication both.

To check for 0 ,

As we know that, 0∈R , so,We have, (2⋅0−7⋅0+0) so (0,0,0)∈W3

Therefore, W3 isn’t empty.

Now, let a1,a2,a3,b1,b2,b3∈R , so2a1−7a2+a3=0∧2b1−7b2+b3=0

Then,(a1,a2,a3)+(b1,b2,b3)=(a1+b1,a2+b2,a3+b3)

So,2(a1+b1)−7(a2+b2)+(a3+b3)=2a1−7a2+a3+2b1−7b2+b3

⇒ 2(a1+b1)−7(a2+b2)+(a3+b3)=0+0

⇒ 2(a1+b1)−7(a2+b2)+(a3+b3)=0

This shows that,∀x,y∈W3,x+y∈W3 and c∈R

It is closed under addition.

Now, let (a1,a2,a3)∈W3 and c∈R , so

⇒ c⋅(a1,a2,a3)=(ca1,ca2,ca3)

⇒ 2ca1−7ca2+ca3=c⋅(2a1−7a2+a3)

⇒ 2ca1−7ca2+ca3=c⋅0

⇒ 2ca1−7ca2+ca3=0

This shows that,c⋅x∈W3∀x∈W3,∀c∈R

It is closed under scalar multiplication.

Since, W3 is a subset of R3 and it satisfies all the conditions of vector space.

The set W3={(a1,a2,a3)∈R3:2a1−7a2+a3=0} is a subspace of R3 .

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 17 Answer

It is given that the set, W4={(a1,a2,a3)∈R3:a1−4a2−a3=0} .

We have to find whether the set is the subspace of R3 under the operations of addition and scalar multiplication defined on R3.

We should check for addition and multiplication both.

To check for 0,

As we know that, 0∈R , so,We have, (0−4⋅0−0)=0 so (0,0,0)∈W4.

Therefore, W4 isn’t empty.

Now, let a1,a2,a3,b1,b2,b3∈R ,

Then,(a1,a2,a3)+(b1,b2,b3)=(a1+b1,a2+b2,a3+b3)

So,(a1+b1)−4(a2+b2)−(a3+b3)=a1−4a2−a3+b1−4b2−b3

⇒ a1−4a2−a3+b1−4b2−b3=0+0

⇒ a1−4a2−a3+b1−4b2−b3=0 .

This shows that,∀x,y∈W4,x+y∈W4 and c∈R

It is closed under addition.

Now, let (a1,a2,a3)∈W3 and c∈R , so c⋅(a1,a2,a3)=(ca1,ca2,ca3)

⇒ ca1−4ca2−ca3=c⋅(a1−4a2−a3)

⇒ ca1−4ca2−ca3=c⋅0

⇒ ca1−4ca2−ca3=0

This shows that,c⋅x∈W4∀x∈W4,∀c∈R

It is closed under scalar multiplication.

As, W4 is a subset of R3 and it satisfies all the conditions of vector space.

The set W4={(a1,a2,a3)∈R3:a1−4a2−a3=0} is a subspace of R3.

Friedberg 5th Edition Chapter 1 Exercise 1.3 Guide Chapter 1 Page 21 Problem 18 Answer

Given: W5={(a1,a2,a3)∈R3:a1+2a2−3a3=1}.To find: verify whether W5 is a subspace of R3 or not.

Analyse whether the zero vector satisfies the condition of W5.

Substitute the value 0 in the equationa1+2a2−3a3=1

⇒ 0+2⋅0−3⋅0=1

As 0≠1, therefore, the zero vector (0,0,0) does not satisfy the condition of W5.

Therefore, the set W5 is not a subspace of R3.

The given subspace W5

={(a1,a2,a3)∈R3:a1+2a2−3a3=1} is not a subspace of R3.

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 19 Answer

Given: W6={(a1,a2,a3)∈R3:5a12−3a22+6a32=0}.

We have to verify whether W6 is a subspace of R3 or not.

Analyse whether the zero vector satisfies the condition of W6.

Analyze whether the zero vector satisfies the given set.

⇒ 5(0)2−3(0)2+6(0)2=0

Therefore, the zero vector (0,0,0) satisfies the condition of W6.

Assume

x=(a1,a2,a3),and y=(b1,b2,b3)be the non-zero vectors in W6

The sum of vectors x+y=(a1,a2,a3)+(b1,b2,b3)

=(a1+b1,a2+b2,a3+b3)

Analyse whether the vector x+y satisfies the conditions of the set W6 or not.

​5(a1+b1)2−3(a2+b2)2+6(a3+b3)2

=5(a12+2a1b1+b12)−3(a22+2a2b2+b22)+6(a32+2a3b3+b32)

=5a12+10a1b1+5b12−3a22−6a2b2−b22+6a32+12a3b3+6b32

=(5a12−3a22+6a32)+(5b12−3b22+6b32)+10a1b1−6a2b2+12a3b3

Substitute the given values,

​=0+0+10a1b1−6a2b2+12a3b3

=10a1b1−6a2b2+12a3b3≠0​

Hence, the set W6 is not a subspace of R3.

The set W6={(a1,a2,a3)∈R3:5a12−3a22+6a32=0} is not a subset of R3.

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 20 Answer

Given that W1={(a1,a2,a3)∈R3:

⇒ a1=3a2 and a3=−a2},

⇒ W3={(a1,a2,a3)∈R3,

⇒ 2a1−7a2+a3=0},

⇒ W4={(a1,a2,a3)∈R3,

⇒ a1−4a2−a3=0}

To find: describe W1∩W3,W1∩W4 and W3∩W4 and observe that each is a surface of R3.

Calculating the representation of W1∩W3={(a1,a2,a3)∈R3:

⇒ a1=3a2,

⇒ a3=−a2,

⇒ 2a1−7a2+a3=0}

⇒ a1−3a2=0,

⇒ a2+a3=0,

⇒ 2a1−7a2+a3=0

Solving the above equations, we get

⇒ a1=0

⇒ a2=0

⇒ a3=0

⇒W1∩W3={0,0,0}

The zero space is a rulespace of every vector space ⇒W1∩W3 is a rulespace of R3.

Calculating the representation of W1∩W3={(a1,a2,a3)∈R3:

⇒ a1=3a2,

⇒ a3=−a2,

⇒ a1−4a2−a3=0}

⇒ a1−3a2=0,

⇒ a2+a3=0,

⇒ a1−4a2−a3=0

⇒a1=3a2,

⇒ −a3=a2

⇒ a1−4a2−a3=0

⇒3a2−4a2+a2=0

⇒0=0

⇒W1∩W3={(a1,a2,a3)∈R3:

⇒ a1=3a2,

⇒ a3=−a2

=W1W1 is a rulespace of R3

⇒W1∩W3 is a rulespace of R3​

Calculating the representation of W3∩W4={(a1,a2,a3)∈R3:

⇒ 2a1−7a2+a3=0,

⇒ a1−4a2−a3=0}

⇒ 2a1−7a2+a3=0, ……(1)

⇒ a1−4a2−a3=0 ……(2)

Equation 2−2 equation 1

given a2+3a3=0a1−4a2−a3=0

⇒a2=−3a3,

⇒ a1=−11a3

⇒W3∩W4={(a1,a2,a3)∈R3:

⇒ a2=−3a3,

⇒ a1=−11a3}

We have to show that W3∩W4 is a rulespace of R3.

We know that W3∩W4 is a ruleset of R3

(0,0,0)=0∈W3∩W4…… (if a3=0)

Let x=(x1,x2,x3),

⇒ y=(y1,y2,y3)

⇒ x2=−3×3,

⇒ x1=−11×3,

⇒ y2=−3y3,

⇒ y1=−11y3

⇒ αx+βy=α(x1,x2,x3)+β(y1,y2,y3)

=(αx1+βy1,αx2+βy2,αx3+βy3)

=(−11(αx3+βy3),−3(αx3+βy3),αx3+βy3)

⇒αx+βy∈W3∩W4

⇒W3∩W4 is a rulespace of R3.

We found that all W3∩W4={(0,0,0)},

⇒ W1∩W4=W1,

⇒ W3∩W4={(a1,a2,a3)∈R3:

⇒ a2=−3a3,

⇒ a1=−11a3} are rulespace of R3.

Linear Algebra 5th Edition Stephen Friedberg Exercise 1.3 Walkthrough Chapter 1 Page 21 Problem 21 Answer

Given: W1={(a1,a2,…,an)∈Fn:a1+a2+⋯+an=0} andW2={(a1,a2,…,an)∈Fn:a1+a2+⋯+an=1}

To prove that W1 is a subspace of Fn but W2 is not.

Verify if the set is closed under addition and scalar multiplication.

Check if the given set is closed under addition and scalar multiplication.

Consider (a1,a2,…,an)+c(b1,b2,…,bn)

Since W1 is a subset of V, the scalar multiplication and vector addition holds in W1 also.

Therefore, (a1,a2,…,an)+c(b1,b2,…,bn)=(a1+cb1,a2+cb2,…,an+cbn)

Now, consider (a1+cb1)+(a2+cb2)+…+(an+cbn)

=(a1+a2+…+an)+c(b1+b2+…+bn)

=0+c(0)

=0

(a1+cb1)+(a2+cb2)+…+(an+cbn)=0⇒(a1+cb1,a2+cb2,…,an+cbn)∈W1

Thus, W1 is a subspace of Fn.

Check whether the zero vector satisfies the condition of W2.

⇒ 0+0+⋯+0=1

⇒ 0≠1

Thus, W2 is a subspace of Fn.

As W1 is closed under addition and scalar multiplication and it contains zero vector, hence it is a subset of Fn.

W2 does not satisfy the zero vector condition, therefore, it is not a subset of Fn.

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 22 Answer

It has been given that W={f(x)∈P(F):f(x)=0 or f(x) has degree n}.

We have to find that if W is a subspace of P(F) if   n≥1.

Suppose f(x)=xn+xn−1,n−1>0 and g(x)=xn

Therefore, f(x)−g(x)=xn−1.

It is a polynomial of degree neither 0 nor n.

Hence, when a=1,b=−1, it can be concluded that af(x)+bg(x) is not in W but f(x),g(x) are in W.

Thus, the set W is not a subspace.

Whena=1, and b=−1, it can be concluded that af(x)+bg(x) is not in W.

Hence, W is not a subspace.

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 23 Answer

It has been given that W={A:Aij=0 whenever i>j}

We have to prove that W forms a subspace of Mm×n(F).

Show that Rij=0 if i>j.

Assume P and Q be upper triangular m×n matrices with components Pij and Qij respectively.

Also, let R=P+Q

Components of R are given by: Rij=Pij+Qij

Rij={​Pij 0

if i≤j

if i>j​+{Qij 0

if i≤j if i>j     ​

={Pij+Qij

0 if i≤j if i>j​

Hence, Rij=0 if i>j

This show that R is an upper triangular matrix.

As, it has been proved that ​Rij=0 if i>j, hence R is an upper triangular matrix.

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 24 Answer

It has been given that: S is a non-empty set, therefore, S≠ϕ.To prove: ​{f∈F(S,F):f(s0)=0}, is a subspace of F(S,F)

​for any s0∈S​

Verify whether it is closed under addition and scalar multiplication and it contains the zero vector.

As S is a non-empty set, therefore, S≠ϕ.

Suppose Ws 0

={f∈F(S,F)};f(s0)=0

Since 0=0 for all s0∈S

Therefore, one condition is satisfied for proving it to be a subspace of F(S,F).

Calculate if it is closed under addition or not.

Let f,g∈Ws0and c,d∈F.

Thus, f(s0)=g(s0)

g(s0)=0

​(cf+dg)(s0)

​=(cf)(s0)+(dg)(so)

=c(f(s0))+d(g(s0))

=c(0)+d(0)

=0​

Hence, (cf+dg)∈Ws​0

Therefore, it can be concluded that it is closed under addition.

Calculate if it is closed under scalar multiplication or not.

​Let f∈Ws​0 and c∈F.

Hence, f(s0)=0.​(cf)(s0)

=c(f(s0))

=c(0)

=0​​

Thus, it can be concluded that (cf)∈Ws​0.

​Since all the three conditions are satisfied, therefore,

{f∈F(S,F):f(s0)=0}, is a subspace of F(S,F) for any s0∈S

As it is closed under addition and scalar multiplication and it contains the zero vector, therefore

{f∈F(S,F):f(s0)=0}, is a subspace of F(S,F) for any s0∈S.

Chapter 1 Exercise 1.3 In Stephen Friedberg’s Notes Page 21 Problem 25 Answer

It has been given that: C(S,F) denotes the set of all functions f∈F(S,F) such that f(s)=0 for all but a finite number of element of S.

To prove: C(S,F) is a subspace of f∈F(S,F).

Verify whether it is closed under addition and scalar multiplication and it contains the zero vector.

Suppose f,g∈C(S,F) and c,d∈F

​Consider (cf+dg)(s0)​​

(cf+dg)(s0)=(cf)(s0)+(dg)(se)

=cf(s0)+dg(s0)

=c(0)+d(0) for all but a finite number of elements of S.

=0 for all but a finite number of elements of S.

Thus, cf+dg∈C(S,F) when f,g∈C(S,F) and c,d∈F.

Therefore, C(S,F) is a subspace of F(S,F).

Hence, proved.

Assume ​(cf+dg)(s0)=(cf)(s0)+(dg)(se)

=cf(s0)+dg(s0)

=c(0)+d(0) for all but a finite number of members of S.

=0 for all but a finite number of members of S.

Thus, cf+dg∈C(S,F)whenf,g∈C(S,F);c,d∈F.

Therefore, C(S,F) is a subspace of F(S,F).

Therefore, proved.

Linear Algebra 5th Edition Chapter 1 Page 21 Problem 26 Answer

It has been given a set of all differentiable real-valued functions defined on R.

To calculate if it is a subspace of C(R) or not.

Verify if it is closed under addition and scalar multiplication and it contains the zero vector to determine if it is a subspace of C(R) or not.

The derivative of a zero function exists, 0′=0

Hence, 0∈D(R).

Thus, one condition is satisfied for proving it to be a subspace of F(S,F).

Calculate if it is closed under addition or not.

Explain the set D(R).

D(R)={f:f is differentiable real valued function on R.

Suppose that f and g are differentiable functions in D(R).

f′ and g′ exists in D(R), therefore, f∈D(R) and g∈D(R).

Therefore, f′+g′=(f+g)′ which implies (f+g)∈D.

Calculate whether it is closed under scalar multiplication or not.

As a constant multiple of a differentiable real valued function is differentiable, hence, c(f′)=(cf)′, thus (cf)∈D.

As all the three conditions are satisfied, therefore, the set of all differentiable real-valued functions defined on R is a subset of C(R).

A set of all differentiable real-valued functions defined on R will be closed under addition and scalar multiplication and it contains the zero vector, hence, it is a subset of C(R).

Linear Algebra 5th Edition Chapter 1 Vector Spaces

Page 13 Problem 1 Answer

The given matrix: M3×4(F)

It is required to write the zero vector of M3×4(F).

Solve this by the use of the definition and formula of matrices.

The given matrix will be M3×4(F)  i.e.,

M3×4(F) includes 3 rows and 4 columns.

Stephen Friedberg Linear Algebra 5th Edition Solutions Chapter 1 Page 13 Problem 2 Answer

The given matrix is:

M=
(1    4  ​2 )
(5​    3  6 )

To find: M13, M21,M22.

Solve this by using the definition and formula of matrices.

The given matrix is:

M=

(1       4    2)
(5     ​3      6)

Read and Learn More Stephen Friedberg Linear Algebra 5th Edition Solutions

Mmn  is the mn th entry of the matrix M i.e., element of the mth row and nth column.

So,

⇒ ​M13=3

⇒ ​M21=4

⇒ ​M22=5​

Hence, M13,M21,M22 is 3,4,5 respectively.

Linear Algebra 5th Edition Chapter 1 Page 13 Problem 3 Answer

Simplifying,

[6   −4​3

3​2      9]

Chapter 1 Exercise 1.2 Vector Spaces Explanation Page 13 Problem 4 Answer

Given matrices and the operation are:

[−6     3   1]

[4      −2  8]+

[7      0     2​]
[−5     −3   0]

It is required to perform the indicated operation.

Solve this by adding the corresponding elements of the two matrices.

Simplifying,

[1    3    3]

[−1 −5    8]

Linear Algebra 5th Edition Chapter 1 Page 13 Problem 5 Answer

The given matrices and the operation are:

4[2     1 ​5]
[0​−3   7]

It is required to perform the indicated operation.

Solve this by multiplying every element of the matrix by the scalar.

Simplifying,

[8    4​  20]
[0​−12  28]

Linear Algebra 5th Edition Friedberg Chapter 1 Guide Page 13 Problem 6 Answer

Given matrices and the operation are:

−5[−6     3    1]
​[ 4      −2    8]

It is required to perform the indicated operation.

Solve this by multiplying every element of the matrix by the scalar.

Simplifying,

[30  −15  −5]
[−20   10 −40]

Linear Algebra 5th Edition Chapter 1 Page 13 Problem 7 Answer

The given polynomials and the operation are:

(2×4−7×3+4x+3)+(8×3+2×2−6x+7)

It is required to perform the indicated operation.

Solve this by adding the corresponding coefficients of the two polynomials.

The given polynomials and operation are:

(2×4−7×3+4x+3)+(8×3+2×2−6x+7)

Adding the corresponding coefficients,

(2+0)x4+(−7+8)x3+(0+2)x2+(4−6)x+(3+7)

Simplifying,

2×4+x3+2×2−2x+10

Hence, (2×4−7×3+4x+3)+(8×3+2×2−6x+7) is equal to 2×4+x3+2×2−2x+10 .

Stephen Friedberg Linear Algebra Vector Spaces Notes Chapter 1 Page 13 Problem 8 Answer

The given polynomials and the operation are:

(−3×3+7×2+8x−6)+(2×3−8x+10)

It is required to perform the indicated operation.

Solve this by adding the corresponding coefficients of the two polynomials.

The given polynomials and operation are:

(−3×3+7×2+8x−6)+(2×3−8x+10)

Adding the corresponding coefficients,

(−3+2)x3+(7+0)x2+(8−8)x+(−6+10)

Simplifying,−x3+7×2+4

Hence, (−3×3+7×2+8x−6)+(2×3−8x+10) is equal to −x3+7×2+4 .

Linear Algebra 5th Edition Chapter 1 Page 13 Problem 9 Answer

The given polynomials and the operation are:

5(2×7−6×4+8×2−3x)

It is required to perform the indicated operation.

Solve this by multiplying every coefficient by the scalar.

The given polynomials and operation are:

5(2×7−6×4+8×2−3x)

Multiplying the coefficients by the scalar,

5⋅2×7−5⋅6×4+5⋅8×2−5⋅3x

Simplifying,

10×7−30×4+40×2−15x

Hence, 5(2×7−6×4+8×2−3x) is equal to 10×7−30×4+40×2−15x .

Page 13 Problem 10 Answer

The given polynomials and the operation are:

3(x5−2×3+4x+2)

It is required to perform the indicated operation.

Solve this by multiplying every coefficient by the scalar.

The given polynomials and operation are:

3(x5−2×3+4x+2)

Multiplying the coefficients by the scalar,

3⋅x5−3⋅6×3+3⋅12x+3⋅6

Simplifying,

3×5−6×3+12x+6

Hence, 3(x5−2×3+4x+2) is equal to 3×5−6×3+12x+6 .

Friedberg Linear Algebra Chapter 1 Solved Examples Chapter 1 Page 14 Problem 11 Answer

Given: the table for Upstream and Downstream Crossings.

It is required to record the upstream and downstream crossings in two 3×3

matrices and verify that the sum of these matrices gives the total number of crossings (both upstream and downstream) categorized by trout species and season.

Solve this by adding the corresponding elements of the two matrices.

The data of the upstream crossings can be represented in 3×3matrices, where the row will represent trout and columns, will represent seasons as:

U=
[8     3       3]
​[3       0      0]
[​1        0     0]

The data of the downstream crossings can be represented in 3×3 matrices, where the row will represent trout and columns, will represent seasons as:

D=

[9     3     1]
[1      0     1]
[​4       0    0]

The total number of crossings can be found by adding the upstream and downstream crossings matrices as:

⇒ ​8+9=17

⇒ ​3+6=9

⇒ ​3+1=4

⇒ ​3+1=4

⇒ ​0+0=0

⇒ ​0+1=1

⇒ ​1+4=5

⇒ ​0+0=0

⇒ ​0+0=0

Therefore the upstream and downstream crossings in two 3×3 matrices is recorded as U=
[8   3   3]
[3     0   0]
[1     0    0] and

D=[9   3    1]
​   [1     0   1]
[ ​ 4    0    0] respectively.

It has been also verified that the sum of these matrices gives the total number of crossings (both upstream and downstream) categorized by trout species and season

Vector Spaces Examples Linear Algebra Friedberg Page 14 Problem 12 Answer

A table for the inventory at the end of May is given. It is also given that the inventory at the end of June is given by the matrix.

A=
[5    6     1]
[​3     2     0]
[1      1    3]
​[ 2       5    3]    interpret 2M−A

It is required to record the data as 3×4 matrix Mand verify that the inventory on hand after the order is filled is described by the matrix 2M.

Solve this by the use of the addition and multiplying with a scalar property of matrices.

Therefore the inventory at the end of May is

[4    5     3]
[2     1     1]
[1     1     2]
[3    4      6] and it is verified that the inventory on hand after the order is filled is defined by the matrix 2M.

Linear Algebra 5th Edition Chapter 1 Page 15 Problem 13 Answer

Given:

f(t)=2t+1 ,

g(t)=1+4t−2t2 ,

h(t)=5t+1

To prove: f=g and

f+g=h .

Solve this by using the fact that functions f and g are the same if and only if:

Domain of f and domain of g are similar. Codomain of f and codomain of g are similar.

f and g have the same value at each element of domain.

It is given that S={0,1},

F=R andf(t)=2t+1 ,

⇒ ​g(t)=1+4t−2t2 ,

⇒ ​h(t)=5t+1

For f=g :

As f,g∈F(S,R) , they have the same domain and codomain.

Checking if f(0)=g(0) and

⇒ ​f(1)=g(1) ,

⇒ ​f(0)=2⋅0+1

⇒ ​f(0)=1

⇒ ​g(0)=1+4⋅0−02

⇒ ​g(0)=1

⇒ ​f(1)=2⋅1+1

⇒ ​f(1)=3

⇒ ​g(1)=1+4⋅1−12

⇒ ​g(1)=3

So, f=g .

For f+g=h :

As f,g,h∈F(S,R) , then f+g∈F(S,R) and they have the same domain and codomain.

Checking if (f+g)(0)=h(0) and

⇒ ​(f+g)(1)=h(1) ,

⇒ ​(f+g)(0)=f(0)+g(0)

⇒ ​(f+g)(0)=1+1

⇒ ​(f+g)(0)=2

⇒ ​h(0)=50+1

⇒ ​h(0)=2

⇒ ​(f+g)(1)=f(1)+g(1)

⇒ ​(f+g)(1)=3+3

⇒ ​(f+g)(1)=6

⇒ ​h(1)=51+1

⇒ ​h(1)=6

So, f+g=h

Hence, it is proved that f=g andf+g=h .

Friedberg Chapter 1 Exercise 1.2 Chapter 1 Page 15 Problem 14 Answer

Given: Vector space is V and x,y∈V and a,b∈F .

It is required to prove that (a+b)(x+y)=ax+ay+bx+by .

Solve this by the use of the definition and properties of vector space.

For (VS7) : ∀a∈F∀x,y∈V

⇒ ​a(x+y)=ax+ay

For (VS8) : ∀b∈F∀x∈V

(a+b)x=ax+bx

Consider V be a vector space over the field F and x,y∈V  and a,b∈F arbitrary.

As a and b are scalars, then so is a+b.(a+b∈F)(∗)

(a+b)(x+y)=(a+b)x+(a+b)y

(a+b)(x+y)=ax+bx+ay+by .

Therefore it has been proven that (a+b)(x+y)=ax+bx+ay+by .

Linear Algebra 5th Edition Chapter 1 Page 15 Problem 15 Answer

The given theorems are Theorem 1.1 and Theorem 1.2(c) in the question.

It is required to prove Corollaries 1 and 2 of Theorem 1.1 and Theorem 1.2(c).

Solve this by the use the definition and properties of Vector space.

Assuming the opposite that there are two different vectors 01 and 02

such that

⇒ ​x+01=x

⇒ ​x+02=x∀x∈V

⇒x+01

=x+02

So,01=02

The vector 0 in (VS3) is Unique.

Assuming the opposite that there are two different vectors y1 and y2

such that

⇒ ​x+y1=0

⇒ ​x+y2=0∀x∈V

⇒x+y1

=x+y2

So,y1=y2

The vector y in (VS4) is Unique.

Hence, vector 0 in (VS3) is unique and vector y in (VS4) is unique.

Linear Algebra 5th Edition Chapter 1 Page 15 Problem 16 Answer

It has been provided in the question that V denotes the set of all differentiable real-valued functions defined on the real line.

To prove that V is a vector space with the operations of addition and scalar multiplication defined.

Solve this by using the definition and properties of Vector space.

Real line is a field. Consider f,g,h∈V be real valued differentiable functions.

Sum of differentiable functions is differentiable and product of a real number with a differentiable function is a differentiable function i.e.,

⇒ ​(f+g)(s)=f(s)+g(s)∈V

⇒ ​(cf)(s)=cf(s)∈V

Commutativity and associativity are satisfied as they are real valued function i.e.,

⇒ ​f+g=g+f

⇒ ​(f+g)+h=f+(g+h) .

Here,f+0=f

⇒ ​f+(−f)=0

Here, 0 is the zero function. These properties will be satisfied by the real valued function.

⇒ ​1f=f

Here, 1 is the real number 1 . This is also satisfying.

Also,(xy)f=x(yf)

⇒ ​x(f+g)=xf+xg

⇒ ​(x+y)f=xf+yf

x,y are real numbers. The given properties are satisfied.

Therefore, the vector space V over field R satisfies all the required properties.

Understanding Vector Spaces With Friedberg Linear Algebra Chapter 1 Page 15 Problem 17 Answer

It has been given that V={0} consists of a single vector 0 and defines 0+0=0 and c0=0 for each scalar c in F .

It is required to prove that V is a vector space over F .

Solve this by the use of the definition and properties of Vector space.

Here it has been given that,

⇒ ​V={0}

⇒ ​0+0=0

⇒ ​c0=0∀c∈F

V has only one element so we need to check all of the conditions for that element.

⇒ ​(VS1):∀x,y∈V,x+y=y+x

⇒ ​0+0=0+0=0

⇒ ​(VS2):∀x,y,z∈V,(x+y)+z=x+(y+z)

⇒ ​(0+0)+0=0+0=0

⇒ ​0+(0+0)=0+0=0

(VS3):∀0v∈V such that 0v+x=x∀x∈V

⇒ ​0v+0=x

⇒ ​0v=0∈V

(VS4):∀x∈V,∃y∈V

such that x+y=0

⇒ ​0+y=0

⇒ ​y=0∈V .

Then,(VS5):∀x∈V,1x=x

⇒ ​0=1⋅0=0

(VS6):∀a,b∈F,∀x∈V,(ab)x=a(bx)

⇒ ​(ab)⋅0=0

⇒ ​a(b⋅0)=a⋅0=0

And,

(VS7):∀a∈F,∀x,y∈V,a(x+y)=ax+ay

⇒ ​a(0+0)=a⋅0=0

⇒ ​a⋅0+a⋅0=0+0=0

Similarly,

(VS8):∀a,b∈F,∀x∈V,(a+b)x=ax+bx

⇒ ​(a+b)⋅0=0

⇒ ​a⋅0+b⋅0=0+0=0 .

Hence, V is a vector space over F .

Linear Algebra 5th Edition Chapter 1 Page 15 Problem 18 Answer

Given: (a1,a2) and (b1,b2) are elements of V and c∈R is defined as

(a1,a2)+(b1,b2)=(a1+b1,a2+b2) and  c(a1,a2)=(ca1,a2) .

To find: whether V is a vector space over R with the operations.

Solve this by using the definition and properties of vector space.

Assume V=R2

+:(a1,a2)+(b1,b2)=(a1+b1,a2+b2)

:c(a1,a2)=(c⋅a1,a2)

For V to be a vector space, rules (VS1)−(VS8) must hold.

(VS8):

Assume α,β∈R and a=(a1,a2)∈V arbitrary.

(α+β)⋅a=αa+βb .

Now,(α+β)⋅a=(α+β)⋅(a1,a2)

⇒ ​(α+β)⋅a=((α+β)a1,a2)

⇒ ​(α+β)⋅a=(αa1+βa1,a2)

Also, αa+βa=α(a1,a2)+β(a1,a2)

⇒ ​αa+βa=(αa1,a2)+(βa1,a2)

⇒ ​αa+βa=(αa1+βa1,a22)

So,(α+β)⋅a≠αa+βb .

Hence, V is not a vector space.

Linear Algebra 5th Edition Chapter 1 Page 15 Problem 19 Answer

Given:

V={(a1,a2,…,an):ai∈Rfori=1,2,…,n}

V is a vector space over R.

To find: Whether V is a vector space over the field of complex numbers with the operations of coordinate wise addition and multiplication.

Solve this by using the definition and properties of vector space.

V is a vector space over the field of F if and only if for every x,y∈V and α,β∈F vector αx+βy is an element of V .

Assume V={(a1,a2,…,an):ai∈C∀i=1,2,…,n} ,

⇒ ​x=(x1,x2,…,xn),

⇒ ​y=(y1,y2,…,yn)∈V andα,β∈R .

Checking whether αx+βy is an element of V ,

⇒ ​αx+βy=α(x1,x2,…,xn)+β(y1,y2,…,yn)

⇒ ​αx+βy=(αx1,x2,…,xn)+(βy1,y2,…,yn)

⇒ ​αx+βy=(αx1+βy1,αx2+βy2,…,αxn+βyn)

As αxi+βyi∈C∀i , the vector αx+βy is an element of V .

V is a vector space over the field of R .

Therefore, V is a vector space over the field of complex numbers with the operations of coordinate wise addition and multiplication.

Stephen Friedberg Chapter 1 5th Edition Breakdown Chapter 1 Page 16 Problem 20 Answer

Given:  V={(a1,a2,…,an):ai∈Rfori=1,2,…,n}

V is a vector space over R.

To find: Whether V is a vector space over the field of complex numbers with the operations of coordinate wise addition and multiplication.

Solve this by using the definition and properties of vector space.

Here, V is a vector space over the field of F if and only if for every x,y∈V and α,β∈F

vector αx+βy is an element of V .

Assume V={(a1,a2,…,an):ai∈R∀i=1,2,…,n} ,

⇒ ​x=(1,1,…,1),

⇒ ​y=(2,2,…,2)∈V andα=i,

⇒ ​β=2i∈C .

Checking whether αx+βy is an element of V,

⇒ ​αx+βy=i(1,1,…,1)+2i(2,2,…,2)

⇒ ​αx+βy=(i,i,…,i)+(4i,4i,…,4i)

⇒ ​αx+βy=(5i,5i,…,5i) .

As 5i∉R , vector αx+βy is not an element of V .

V is not a vector space over the field of C .

Therefore, V is not a vector space over the field of complex numbers with the operations of coordinate wise addition and multiplication.

Linear Algebra 5th Edition Chapter 1 Page 16 Problem 21 Answer

Given that V denotes the set of all m×n matrices with real entries and F is the field of rational numbers.

To find: Whether V is a vector space over the field of rational numbers with the usual definitions of matrix addition and multiplication.

Solve this by using the definition and properties of vector space.

Here,V is a vector space over the field of F if and only if for every x,y∈V and α,β∈F vector αx+βy is an element of V.

Assume V={A=(aij)∈Mm×n:aij∈R} ,x=(xij),

y=(yij)∈V andα,β∈Q .

Checking whether αX+βY is an element of V,

⇒ ​αx+βy=α(xij)+β(yij)

⇒ ​αx+βy=(αxij)+(βyij)

⇒ ​αx+βy=(αxij+βyij)

As αxij+βyij∈R∀i , the vector αX+βY is an element of V.

V is not a vector space over the field of Q .

Therefore, V is a vector space over the field of Q with the usual definitions of matrix addition and multiplication.

Linear Algebra 5th Edition Chapter 1 Page 16 Problem 22 Answer

Given: V={(a1,a2):a1,a2∈F} and c∈F , (a1,a2)∈V and is defined as c(a1,a2)=(a1,0) .

To find: whether V is a vector space over F with the operations.

Solve this by using the definition and properties of vector space.

ConsiderV=F2

+:(a1,a2)+(b1,b2)=(a1+b1,a2+b2)

:c(a1,a2)=(a1,0)

For V to be a vector space, rules (VS1)−(VS8) must hold.

(VS5):

Assume a=(a1,a2)∈V ,

1⋅a=a .

Now,1⋅a=1⋅(a1,a2)

1⋅a=(a1,0)

So,1⋅a≠a.

Therefore, V is not a vector space.

Linear Algebra 5th Edition Chapter 1 Page 16 Problem 23 Answer

Given: V={(a1,a2):a1,a2∈R} and (a1,a2),(b1,b2)∈V , c∈R is defined as

(a1,a2)+(b1,b2)=(a1+2b1,a2+3b2) and

c(a1,a2)=(ca1,ca2) .

To find:  whether V is a vector space over R with the operations.

Solve this by using the definition and properties of vector space.

Consider V=R2

+:(a1,a2)+(b1,b2)=(a1+2b1,a2+3b2)

:c(a1,a2)=(ca1,ca2)

For V to be a vector space, rules (VS1)−(VS8) must hold.

(VS2):

Assume a=(a1,a2) ,

b=(b1,b2) ,

c=(c1,c2)∈V ,

(a+b)+c=a+(b+c) .

Now,

⇒ ​(a+b)+c=((a1,a2)+(b1,b2))+(c1,c2)

⇒ ​(a+b)+c=(a1+2b1,a2+3b2)+(c1,c2)

⇒ ​(a+b)+c=(a1+2b1+2c1,a2+3b2+3c2)

Also,

⇒ ​a+(b+c)=(a1,a2)+((b1,b2)+(c1,c2))

⇒ ​a+(b+c)=(a1,a2)+(b1+2c1,b2+3c2)

⇒ ​a+(b+c)=(a1+2b1+4c1,a2+3b2+9c2)

So,

(a+b)+c≠a+(b+c) .

Therefore, V is not a vector space.

Chapter 1 Exercise 1.2 Vector Spaces Explanation Page 16 Problem 24 Answer

Given: V={(a1,a2):a1,a2∈R} and (a1,a2)∈V , c∈R is defined as

c(a1,a2)={(0,0)ifc=0(ca1,a​2c)ifc≠0 .

To find: whether V is a vector space over R with the operations.

Solve this by using the definition and properties of vector space.

Consider V=R2+:(a1,a2)+(b1,b2)=(a1+2b1,a2+3b2)

:c(a1,a2)={(0,0)ifc=0(ca1,a2c)ifc≠0

For V to be a vector space, rules (VS1)−(VS8) must hold.

(VS8):

Assume α,β∈R and a=(a1,a2)∈V arbitrary.

(α+β)⋅a=αa+βb

1⋅a≠0,β≠0 .

Now,(α+β)⋅a=(α+β)⋅(a1,a2)

(α+β)⋅a=((α+β)a1,a2

α+β)(α+β)⋅a=(αa1+βa1,a2α+β)

Also,

⇒ ​αa+βb=α(a1,a2)+β(a1,a2)

⇒ ​αa+βb=(αa1,a2α)+(βa1,a2β)

⇒ ​αa+βb=(αa1+βa1,(α+β)a2αβ)

So,

(α+β)⋅a≠αa+βb .

Therefore, V is not a vector space.

Linear Algebra 5th Edition Chapter 1 Page 16 Problem 25 Answer

Given: V denote the set of all real-valued functions f defined on the real line such that f(1)=0.

We need to prove that V is a vector space with the operations of addition and scalar multiplication.

We will use the 8 conditions given in the example 3.

Let f,g∈V and let c∈R be a scalar, therefore, f(1)=g(1)=0. By applying the properties of real values functions , we obtain:

(f+g)(1)=f(1)+g(1)=0∈V

(cf)(1)=c.1=0∈V​

Now, let’s show that other conditions are also satisfied. Let f,g,h∈V and let a,b∈R be scalars, therefore,

f(1)=g(1)=h(1)=0. Now, we have:

1.for all t∈R, we have:

⇒ ​(f+g)(t)=f(t)+g(t)

⇒ ​g(t)+f(t)=(g+f)(t)

⇒ ​(g+f)(t)=g+f

​2.for all t∈R, we have:

⇒ ​[f+(g+h)](t)=f(t)+(g+h)(t)

⇒ ​f(t)+(g+h)(t)=f(t)+g(t)+h(t)

⇒ ​f(t)+g(t)+h(t)=[(f+g)​+h](t)]

⇒ ​[(f+g)+h](t)]=(f+g)+h

​3.Define 0 be the constant function such that 0(t)=0 for all t∈R, then for all t∈R, we have:

⇒ ​(0+f)(t)=(f+0)(t)

⇒ ​(f+0)(t)=f(t)+0(t)

⇒ ​f(t)+0(t)=f(t)

f(t)=f

​4.Define −f be the function for all t∈R, then for all t∈R we have:

⇒ ​(f+(−f))(t)=(−f+f(t))

⇒ ​(−f+f(t))=f(t)+(−f(t))

⇒ ​f(t)+(−f(t))=f(t)−f(t)

⇒ ​f(t)−f(t)=0

⇒f+(−f)=0

5.For all t∈R, we have:

⇒ ​(1f)(t)=1⋅f(t)

1⋅f(t)=f(t)⇒1f=f

6.For all t∈R , we have:

⇒ ​[(ab)f]t=(ab)[f(t)]

⇒ ​(ab)[f(t)]=a[bf(t)]a[(bf)(t)]

⇒(ab)f=a(b)f

​7.For all t∈R, we have:

⇒ ​[a(f+g](t)=a[(f+g)](t)

⇒ ​a[(f+g)](t)=a[f(t)+g(t)]

⇒ ​(af)(t)+(ag)(t)=(af+ag)(t)​

⇒a(f+g)=af+ag

8.For all t∈R, we have:

⇒ ​[(a+b)f]t=(a+b)[f(t)]

⇒ ​(a+b)[f(t)]=a[f(t)]+b[f(t)]​

⇒(a+b)f=af+bf

​From the above discussion, it is proved that V is a vector space with the operations of addition and scalar multiplication.

Linear Algebra 5th Edition Friedberg Chapter 1 Guide Page 16 Problem 26 Answer

Given matrix: Mm×n(Z2).

To find: calculate the number of matrices present in the vector space.

Solve this by using the definition and properties of vector space.

The field Z2 includes two elements, that is 0 and 1 which means that for each entry of matrix in Mm×n

(F) we have two choices and matrix on its own has mn entries.

Therefore, Mm×n(F) contains 2mn elements.

We obtained that, Mm×n(F) contains  2mn elements.

Linear Algebra 5th Edition Chapter 1 Vector Spaces

Page 6 Problem 1 Answer

Given: (3,−2,4) and (−5,7,1).

To find:  the equation of the line that passes through the mentioned points in space.

Assume A=(3,−2,4) and B=(−5,7,1) .

Then calculate c=B−A, and find the equation of line using the formula,

⇒ x=A+tc .

Calculate the endpoint c,

⇒ c=B−A

⇒ c=(−5,7,1)−(3,−2,4)

⇒ c=(−8,9,−3)

Find the equation of line,

⇒ x=A+tc

⇒ x=(3,−2,4)+t(−8,9,−3)

The equation of the line through vectors A and B will be,

⇒ x=(3,−2,4)+t(−8,9,−3) .

Read and Learn More Stephen Friedberg Linear Algebra 5th Edition Solutions

Vector spaces in Linear Algebra Stephen Friedberg 5th Edition Chapter 1 Exercises Page 6 Problem 2 Answer

Given: (2,4,0) and (−3,−6,0).

To find: the equation of the line that passes through the mentioned points in space.

Assume A=(2,4,0) and B=(−3,−6,0) .

Then find c=B−A, and calculate the equation of line using the formula,

Calculate the endpoint c,

⇒ c=B−A

⇒ c=(−3,−6,0)−(2,4,0)

⇒ c=(−5,−10,0)

Calculate the equation of line,

⇒ x=A+tc

⇒ x=(2,4,0)+t(−5,−10,0)

The equation of the line through vectors A and B will be x=(2,4,0)+t(−5,−10,0).

Linear Algebra 5th Edition Chapter 1 Page 6 Problem 3 Answer

Page 6 Problem 4 Answer

Given points: (−2,−1,5) and (3,9,7).

To find: the equation of the line that passes through the given points in space.

Assume A=(−2,−1,5) and B=(3,9,7) .

Then find c=B−A, and calculate the equation of line using the formula,

Calculate the endpoint c,

⇒ c=B−A

⇒ c=(3,9,7)−(−2,−1,5)

⇒ c=(5,10,2)

The equation of line,

⇒ x=A+tc

⇒ x=(−2,−1,5)+t(5,10,2)

The equation of the line through vectors A and B will be x=(−2,−1,5)+t(5,10,2).

Linear Algebra 5th Edition Stephen Friedberg Chapter 1.1 Vector Spaces Explanation Chapter 1 Page 6 Problem 5 Answer

Given points: (2,−5,−1),(0,4,6),(−3,7,1)

To find: the equation of the plane which contains the given points.

Assume          A=(2,−5,−1) B=(0,4,6) C=(−3,7,1)

and then calculate the endpoints originating from A and terminating at C and B as v and u respectively to calculate the equation of plane as x=A+su+tv

Calculate the endpoint u,

⇒ u=B−A

⇒ u=(0,4,6)−(2,−5,−1)

⇒ u=(−2,9,7)

Similarly, the endpoint v,

⇒ v=C−A

⇒ v=(−3,7,1)−(2,−5,−1)

⇒ v=(−5,12,2)

The equation of the plane containing the given points will be,

⇒ x=A+su+tv

⇒ x=(2,−5,−1)+s(−2,9,7)+t(−5,12,2)

The equation of the plane containing the mentioned points will be,

⇒ x=(2,−5,−1)+s(−2,9,7)+t(−5,12,2) .

Page 6 Problem 6 Answer

Points are given in the question that(3,−6,7),(−2,0,−4),(5,−9,2).

To find: the equation of the plane containing the given points.

Assume

⇒ A=(3,−6,7)

⇒ B=(−2,0,−4)

C=(5,−9,−2) and calculate the endpoints originating from A and terminating at C and B as v and u respectively to calculate the equation of plane as x=A+su+tv

Calculate the endpoint u,

⇒ u=B−A

⇒ u=(−2,0,−4)−(3,−6,7)

⇒ u=(−5,6,−11)

Similarly calculate the endpoint v,

⇒ v=C−A

⇒ v=(5,−9,−2)−(3,−6,7)

⇒ v=(2,−3,−9)

Calculate the equation of the plane containing the given points,

⇒ x=A+su+tv

⇒ x=(3,−6,7)+s(−5,6,−11)+t(2,−3,−9)

The equation of the plane which contains the given points will be x=(3,−6,7)+s(−5,6,−11)+t(2,−3,−9).

Key Concepts Vector Spaces Chapter 1 Friedberg Linear Algebra 5th Edition Page 6 Problem 7 Answer

Points given are (−8,2,0),(1,3,0),(6,−5,0) .

To find the equation of the plane containing the given points.

Assume

⇒ A=(−8,2,0)

⇒ B=(1,3,0)

C=(6,−5,0) and then calculate the endpoints originating from A and terminating at C and B as v and u respectively to calculate the equation of plane as x=A+su+tv

Calculate the endpoint u,

⇒ u=B−A

⇒ u=(1,3,0)−(−8,2,0)

⇒ u=(9,1,0)

Similarly calculate the endpoint v,

⇒ v=C−A

⇒ v=(6,−5,0)−(−8,2,0)

⇒ v=(14,−7,0)

Calculate the equation of the plane containing the given points,

⇒ x=A+su+tv

⇒ x=(−8,2,0)+s(9,1,0)+t(14,−7,0)

The equation of the plane containing the given points will be,

⇒ x=(−8,2,0)+s(9,1,0)+t(14,−7,0) .

Page 6 Problem 8 Answer

Given points: (1,1,1),(5,5,5),(−6,4,2)

To find: the equation of the plane containing the given points.

Assume

⇒ A=(1,1,1)

⇒ B=(5,5,5)

C=(−6,4,2) and then calculate the endpoints originating from A and terminating at C and B as v and u respectively to find the equation of plane as x=A+su+tv

Calculate the endpoint u,

⇒ u=B−A

⇒ u=(5,5,5)−(1,1,1)

⇒ u=(4,4,4)

Calculate the endpoint v,

⇒ v=C−A

⇒ v=(−6,4,2)−(1,1,1)

⇒ v=(−7,3,1)

Calculate the equation of the plane containing the mentioned points,

⇒ x=A+su+tv

⇒ x=(1,1,1)+s(4,4,4)+t(−7,3,1)

The equation of the plane containing the given points will be x=(1,1,1)+s(4,4,4)+t(−7,3,1).

Linear Algebra Vector Spaces Solved Examples Stephen Friedberg Chapter 1 Page 6 Problem 9 Answer

It has been given a property that ‘There exists a vector denoted 0 such that x+0=x for each vector x.

To find: the coordinates of the vector 0 in the Euclidean plane that is satisfying the given property

To calculate that, the vector will be satisfying the vector rules of addition.

Vector law of addition will be,

⇒ (x1,x2)+(01+02)=(x1,x2)

Where (x1,x2)∈R

After following the rules of vector addition,

⇒ (x1+01,x2+02)=(x1,x2)

⇒ x1+01=x1

⇒ 01=x1−x1

⇒ 01=0

In the same way, 02=0

The coordinates of the vector 0 in the Euclidean plane that satisfies the mentioned property will be (0,0).

Page 6 Problem 10 Answer

We have to prove that the vector x emanates from the origin of the Euclidean plane and terminates at the point with coordinates (a1,a2).

Then the vector tx that emanates from the origin terminates at the point with coordinates (ta1,ta2).

Vector x⃗ will be emanating from the origin and terminates at (a1,a2) :x⃗=(a1,a2)−(0,0)

x⃗=(a1,a2)Assume tx⃗ is then,tx⃗=t(a1,a2)

tx⃗=(ta1,ta2)

As we know, tx⃗ emanates from the origin, so,

(ta1,ta2)+(0,0)=(ta1,ta2)

The vector x emanates from the origin of the Euclidean plane and terminates at the point with coordinates (a1,a2), then the vector tx that emanates from the origin terminates at the point with coordinates (ta1,ta2).

Linear Algebra 5th Edition Chapter 1 Page 6 Problem 11 Answer

We need to prove that the diagonals of the parallelogram bisect each other.

For proving this, we have to assume a parallelogram ABCD and diagonals intersect each other at O.

And further by the use of congruent triangles, the given will be proved.

Sketch a parallelogram ABCD and diagonals intersect each other at O,

Assume △AOB and △DOC,

⇒ ∠AOC=∠DOC ..(opposite angles)

⇒ AB=DC ..(opposite parallel sides)

⇒ ∠ABO=∠ODC (alternate interior angles)

So, △AOD≅△DOC

Therefore, we can conclude by saying

​⇒ AO=OC

⇒ DO=BO​

The diagonals of the parallelogram will be bisecting each other.