Texas TEKS Geometry

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Select the number of each type of objective: (Selecting Random will randomly generate all subtypes) Click on any title to see the free sample worksheet. (only the first few samples are free) (Random) (2.A) Coordinate and transformational geometry. Determine the coordinates of a point that is a given fractional distance less than one from one end of a line segment to the other in one- and two-dimensional coordinate systems, including finding the midpoint; a. Graphing a Point using Coordinates b. Graphing Multiple Points using Coordinates c. Identifying Coordinates given a Graph d. Identifying Multiple sets of Coordinates given a Graph e. Identifying Quadrants given a Point f. Identifying Quadrants given Multiple Points g. Using the Midpoint Formula h. Graphing Rational Numbers on a Number Line i. Graphing Irrational Numbers on a Number Line (Random) (2.B) Coordinate and transformational geometry. Derive and use the distance, slope, and midpoint formulas to verify geometric relationships, including congruence of segments and parallelism or perpendicularity of pairs of lines; a. Using the Midpoint Formula (Finding the Midpoint) b. Using the Midpoint Formula (Finding an Endpoint) c. Using the Distance Formula d. Using the Formula for Slope e. Identifying Congruent Segments f. Using Point, Line, and Plane Postulates g. Finding Points using Slope h. Finding Points using Distance (Random) (2.C) Coordinate and transformational geometry. Determine an equation of a line parallel or perpendicular to a given line that passes through a given point. a. Writing Equations of Parallel Lines b. Writing Equations of Perpendicular Lines c. Identifying Parallel, Perpendicular, and Oblique from Equations d. Identifying Parallel, Perpendicular, and Skew (Random) (3.A) Coordinate and transformational geometry. Describe and perform transformations of figures in a plane using coordinate notation; a. Applying Rotations b. Applying Reflections c. Applying Translations (with Vectors) d. Finding the Minimum Distance between two Points Touching a Line (Random) (3.B) Coordinate and transformational geometry. Determine the image or pre-image of a given two-dimensional figure under a composition of rigid transformations, a composition of non-rigid transformations, and a composition of both, including dilations where the center can be any point in the plane; a. Composition of Transformations b. Applying Glide Reflections c. Reflecting Twice (Random) (3.C) Coordinate and transformational geometry. Identify the sequence of transformations that will carry a given pre-image onto an image on and off the coordinate plane; a. Identifying the Transformation (Rotation, Reflection, Translation, or Glide Reflection) b. Classifying Frieze Patterns (Random) (3.D) Coordinate and transformational geometry. Identify and distinguish between reflectional and rotational symmetry in a plane figure. a. Identifying Line Symmetry b. Identifying Rotational and Point Symmetry (Random) (4.A) Logical argument and constructions. Distinguish between undefined terms, definitions, postulates, conjectures, and theorems; a. Defining Common Notation b. Identifying Field Properties c. Identifying Properties of Equality d. Identifying Reflexive, Symmetric and Transitive e. Starting Proofs -- Give the Reason for the Conclusion (Random) (4.B) Logical argument and constructions. Identify and determine the validity of the converse, inverse, and contrapositive of a conditional statement and recognize the connection between a biconditional statement and a true conditional statement with a true converse; a. Identifying Hypothesis and Conclusion (Easier) b. Identifying Hypothesis and Conclusion c. Finding Converse (Easier) d. Relating Biconditionals to Conditional Statements and their Converses e. Finding Converse, Inverse, Contrapositive, and Biconditionals (Easier) f. Finding Converse, Inverse, Contrapositive, and Biconditionals g. Translating into Symbolic Form h. Translating from Symbolic Form i. Reading Venn Diagrams j. Identifying Union, Intersection, Complement, Etc. Venn Diagrams k. Using the Laws of Syllogism and Detachment l. Using Induction (Random) (4.C) Logical argument and constructions. Verify that a conjecture is false using a counterexample; a. Finding a Counterexample (Easier) b. Finding a Counterexample c. Finding a Counterexample (From Algebra) (Random) (4.D) Logical argument and constructions. Compare geometric relationships between Euclidean and spherical geometries, including parallel lines and the sum of the angles in a triangle. a. Identifying Complementary, Supplementary, and Congruent Angles b. Using Complementary, Supplementary, and Congruent Angles c. Using the Definition of Bisect d. Using the Vertical Angle Theorem e. Using the Linear Pair Postulate f. Naming Angle Pairs when given Two Lines and a Transversal g. Identifying Angle Relationships when given Two Parallel Lines and a Transversal (Random) (5.A) Logical argument and constructions. Investigate patterns to make conjectures about geometric relationships, including angles formed by parallel lines cut by a transversal a. Deciding when Lines are Parallel Given Two Lines and a Transversal b. Finding the value of x to prove two Lines are Parallel c. Using the Triangle Sum Theorem to Find Angle Measures d. Using the Exterior Angle Theorem to Find Angle Measures e. Finding Angle Measures (Combinations of the Above) (Random) (5.A) Logical argument and constructions. Investigate patterns to make conjectures about geometric relationships, including criteria required for triangle congruence a. Using Triangle Congruence Theorems b. Proving Congruent with Coordinate Proofs (Random) (5.A) Logical argument and constructions. Investigate patterns to make conjectures about geometric relationships, including special segments of triangles a. Using Perpendicular Bisectors b. Using Angle Bisectors c. Identifying Angle Bisectors, Perpendicular Bisectors, Medians, Altitudes, and Midsegments d. Using Properties of the Circumcenter e. Using Properties of the Incenter f. Using Properties of the Centroid g. Identifying Properties and Names of the Concurrent Points (Random) (5.A) Logical argument and constructions. Investigate patterns to make conjectures about geometric relationships, including diagonals of quadrilaterals a. Finding Angles, Sides, and Diagonals in Parallelograms b. Finding Angles, Sides, and Diagonals in Trapezoids c. Identifying Properties of Trapezoids and Kites d. Using Midsegments in Trapezoids e. Identifying Properties of Special Quadrilaterals (Random) (5.A) Logical argument and constructions. Investigate patterns to make conjectures about geometric relationships, including interior and exterior angles of polygons a. Naming Polygons b. Finding Angles in Polygons c. Using the Angles in Polygons to Identify the Polygon d. Placing figures Conveniently in the Coordinate Plane e. Using Tessellation Problems when Finding Angles f. Combining multiple cases of Interior or Exterior Angles of Regular Polygons (Random) (5.A) Logical argument and constructions. Investigate patterns to make conjectures about geometric relationships, including special segments and angles of circles choosing from a variety of tools; a. Finding Arcs/Angles (Central Angle) b. Finding Arcs/Angles (Inscribed Angles) c. Finding Miscellaneous Angles d. Using Diameters and Chords e. Finding Chord Length f. Combining Triangles/Quadrilaterals And Circles (Angles) g. Combining Triangles/Quadrilaterals And Circles (Segments) (Random) (5.B) Logical argument and constructions. Construct congruent segments, congruent angles, a segment bisector, an angle bisector, perpendicular lines, the perpendicular bisector of a line segment, and a line parallel to a given line through a point not on a line using a compass and a straightedge; a. Identifying Constructions b. Using Constructions (Basic) c. Identifying Construction Steps (Random) (5.C) Logical argument and constructions. Use the constructions of congruent segments, congruent angles, angle bisectors, and perpendicular bisectors to make conjectures about geometric relationships; a. Using Constructions (Complex) (Random) (5.D) Logical argument and constructions. Verify the Triangle Inequality theorem using constructions and apply the theorem to solve problems. a. Determining if a Triangle Exists b. Ordering Sides and Angles of a Triangle c. Word Problems	(Random) (6.A) Proof and congruence. Verify theorems about angles formed by the intersection of lines and line segments, including vertical angles, and angles formed by parallel lines cut by a transversal and prove equidistance between the endpoints of a segment and points on its perpendicular bisector and apply these relationships to solve problems; a. Filling in Reasons in Algebraic Proofs b. Doing Algebraic Proofs c. Using the Segment Addition Postulate d. Using the Angle Addition Postulate e. Filling in Reasons for Proofs Involving Transversals f. Proofs Involving Transversals (Random) (6.B) Proof and congruence. Prove two triangles are congruent by applying the Side-Angle-Side, Angle-Side-Angle, Side-Side-Side, Angle-Angle-Side, and Hypotenuse-Leg congruence conditions; a. Filling in Reasons for Proving Triangles are Congruent b. Proving Triangles are Congruent c. Filling in Reasons when Using CPCTC in Proofs d. Using CPCTC in Proofs (Random) (6.C) Proof and congruence. Apply the definition of congruence, in terms of rigid transformations, to identify congruent figures and their corresponding sides and angles; a. Writing Congruence Statements for Triangles (Random) (6.D) Proof and congruence. Verify theorems about the relationships in triangles, including proof of the Pythagorean Theorem, the sum of interior angles, base angles of isosceles triangles, midsegments, and medians, and apply these relationships to solve problems; a. Using the Pythagorean Theorem b. Using the Pythagorean Theorem Converse (Classifying Triangles) c. Using Midsegments in Triangles d. Finding the Endpoints of the Triangle given the Endpoints of the Midsegments (Random) (6.E) Proof and congruence. Prove a quadrilateral is a parallelogram, rectangle, square, or rhombus using opposite sides, opposite angles, or diagonals and apply these relationships to solve problems. a. Identifying Properties of Parallelograms b. Proving Quadrilaterals are Parallelograms c. Proving Quadrilaterals are Special Parallelograms using Coordinate proofs (Random) (7.A) Similarity, proof, and trigonometry. Apply the definition of similarity in terms of a dilation to identify similar figures and their proportional sides and the congruent corresponding angles; a. Writing Similarity Statements and Statements of Proportion for Triangles b. Finding the Scale Factor c. Word Problems with Similar Triangles d. Solving Scale Model Problems (Random) (7.B) Similarity, proof, and trigonometry. Apply the Angle-Angle criterion to verify similar triangles and apply the proportionality of the corresponding sides to solve problems. a. Using Triangle Similarity Theorems b. Filling in Reasons when Proving Triangles are Similar c. Proving Triangles are Similar (Random) (8.A) Similarity, proof, and trigonometry. Prove theorems about similar triangles, including the Triangle Proportionality theorem, and apply these theorems to solve problems; a. Finding the Scale Factor b. Using Proportions in Similar Triangles c. Word Problems with Similar Triangles (Random) (8.B) Similarity, proof, and trigonometry. Identify and apply the relationships that exist when an altitude is drawn to the hypotenuse of a right triangle, including the geometric mean, to solve problems. a. Using Right Triangles with Altitudes (Random) (9.A) Similarity, proof, and trigonometry. Determine the lengths of sides and measures of angles in a right triangle by applying the trigonometric ratios sine, cosine, and tangent to solve problems; a. Finding Trigonometric Functions from Triangles b. Solving Ratios with Trigonometric Functions c. Using Trigonometry (Sin, Cos, Tan) to find Side Lengths d. Using Inverse Trigonometric Functions (Sin^-1, Cos^-1, Tan^-1) to find Angles e. Solving Right Triangles f. Finding Area of Right Triangles (Uses Trig!) g. Using sin²(A) + cos²(A) = 1 h. Using sin(A) = cos(90°-A) (Random) (9.B) Similarity, proof, and trigonometry. Apply the relationships in special right triangles 30°-60°-90° and 45°-45°-90° and the Pythagorean theorem, including Pythagorean triples, to solve problems. a. Simplifying Radicals b. Finding the Geometric Mean c. Using Special Right Triangles (Random) (10.A) Two-dimensional and three-dimensional figures. Identify the shapes of two-dimensional cross-sections of prisms, pyramids, cylinders, cones, and spheres and identify three-dimensional objects generated by rotations of two-dimensional shapes; a. Using Scale Drawings b. Using Perspective Drawings c. Using Blueprints d. Creating a 2-D Representation of a 3-D Object e. Creating a 3-D Object from 2-D Representations f. Creating a 3-D Object from Nets (Random) (10.B) Two-dimensional and three-dimensional figures. Determine and describe how changes in the linear dimensions of a shape affect its perimeter, area, surface area, or volume, including proportional and non-proportional dimensional change. a. Using Proportional Reasoning with Similar Objects b. Using Dimension Changes to Find Volume and Surface Area (Random) (11.A) Two-dimensional and three-dimensional figures. Apply the formula for the area of regular polygons to solve problems using appropriate units of measure; a. Using The Apothem to find Area of a Polygon b. Using The Radius to find Area of a Polygon c. Using The Side Length to find Area of a Polygon (Random) (11.B) Two-dimensional and three-dimensional figures. Determine the area of composite two-dimensional figures comprised of a combination of triangles, parallelograms, trapezoids, kites, regular polygons, or sectors of circles to solve problems using appropriate units of measure; a. Finding Area of Special Quadrilaterals b. Finding Area (Random) (11.C) Two-dimensional and three-dimensional figures. Apply the formulas for the total and lateral surface area of three-dimensional figures, including prisms, pyramids, cones, cylinders, spheres, and composite figures, to solve problems using appropriate units of measure; a. Finding the Surface Area b. Finding Surface Area of Pyramids and Cones (with distractors) c. Solving for x Given Surface Area (Random) (11.D) Two-dimensional and three-dimensional figures. Apply the formulas for the volume of three-dimensional figures, including prisms, pyramids, cones, cylinders, spheres, and composite figures, to solve problems using appropriate units of measure. a. Finding the Volume Problems b. Solving for x Given Volume c. Solving Word Problems d. Finding Area and Perimeter of Rectangles and Squares (Given Coordinates) e. Finding Area and Perimeter of Triangles (Given Coordinates) f. Finding Area and Circumference of Circles (Given Coordinates) (Random) (12.A) Circles. Apply theorems about circles, including relationships among angles, radii, chords, tangents, and secants, to solve non-contextual problems; a. Reviewing Circle Vocabulary b. Using Tangent Properties c. Identifying a Tangent to a Circle (using Pythagorean Theorem) (Random) (12.B) Circles. Apply the proportional relationship between the measure of an arc length of a circle and the circumference of the circle to solve problems; a. Finding Arc Length (Random) (12.C) Circles. Apply the proportional relationship between the measure of the area of a sector of a circle and the area of the circle to solve problems; a. Finding Area of a Sector (Random) (12.D) Circles. Describe radian measure of an angle as the ratio of the length of an arc intercepted by a central angle and the radius of the circle; a. Converting from Radians to Degrees b. Converting from Degrees to Radians c. Using the Unit Circle and Arc Length to see Radians (Random) (12.E) Circles. Show that the equation of a circle with center at the origin and radius r is x² + y² = r² and determine the equation for the graph of a circle with radius r and center (h, k), (x - h)² + (y - k)² =r². a. Identifying and Creating Equations of Circles b. Creating Equations of Circles from 2 Key Points c. Identify points as Inside, Outside, or On a Circle Given the Equation (Random) (13.A) Probability. Develop strategies to use permutations and combinations to solve contextual problems; a. Identifying Permutations and Combinations b. Calculating Permutations (And other cases where order matters) c. Calculating Combinations d. Calculating Rearrangements of Words (Random) (13.B) Probability. Determine probabilities based on area to solve contextual problems; a. Finding Geometric Probabilities (Random) (13.C) Probability. Identify whether two events are independent and compute the probability of the two events occurring together with or without replacement; a. Finding Probability of Dependent Events b. Notion of Independence vs. Dependence (Random) (13.D) Probability. Apply conditional probability in contextual problems; a. Addition Rule, Multiplication Rule, Conditional Probabilities, and Independence (Random) (13.E) Probability. Apply independence in contextual problems. a. Finding Probability of Independent Events
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