Let A = {1,2,3,4} and B = {a,b,c}. Define the relation f from A to B by f = {(1,b), (2,a), (3,c), (4,b)}. Is f a function? (1) Yes (2) No.

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Let A = {1,2,3,4} and B = {a,b,c}. Define the relation f from A to B by f = {(1,b), (2,a), (3,c), (4,b)}. Is f a function? (1) Yes (2) No

Let A = {1,2,3,4} and B = {a,b,c}. Define the relation f from A to B by f = {(1,b), (2,a), (3,c), (4,b)}. Is f onto? (1) Yes (2) No

Define f: R  R by f(x) = x 2. Is f onto? (1) Yes (2) No

Define f: Z  Z by f(x) = x + 2. Is f onto? (1) Yes (2) No

Define f: R  R by f(x) = [x]. Is f onto? (1) Yes (2) No

Define f: R  Z by f(x) = [x]. Is f onto? (1) Yes (2) No

Define f: R´R  R by f(x,y) = x  y. (f is the multiplication function). Is f onto? (1) Yes (2) No

Define f: R  R´R by f(x) = (x, 2x). Is f onto? (1) Yes (2) No

Let A = {1,2,3,4} and B = {a,b,c}. Define the relation f from A to B by f = {(1,b), (2,a), (3,c), (4,b)}. Is f one-to-one? (1) Yes (2) No

Define f: R  R by f(x) = x 2. Is f one-to-one? (1) Yes (2) No

Define f: Z  Z by f(x) = x + 2. Is f one-to-one? (1) Yes (2) No

Define f: R  Z by f(x) = [x]. Is f one-to-one? (1) Yes (2) No

Define f: R´R  R by f(x,y) = x  y. (f is the multiplication function). Is f one-to-one? (1) Yes (2) No

Define f: R  R´R by f(x) = (x, 2x). Is f one-to-one? (1) Yes (2) No