PHYSICAL SCIENCE
MOTION
Graphical Representation of Motion, Distance-Time Graphs, Velocity-Time Graphs
Here’s a comprehensive list of short-type questions and answers related to the graphical representation of motion, distance-time graphs, and velocity-time graphs that are often asked in competitive exams. These questions cover various aspects including interpretation, analysis, and the applications of these graphs.
Distance-Time Graphs
Q1: What does a straight line in a distance-time graph indicate?
A1: It indicates uniform motion with constant speed.
Q2: What does a horizontal line on a distance-time graph represent?
A2: It represents an object at rest.
Q3: How can you determine speed from a distance-time graph?
A3: Speed is determined by the slope of the distance-time graph.
Q4: What does a curved line on a distance-time graph signify?
A4: It signifies changing speed, which means the object is accelerating or decelerating.
Q5: How is average speed calculated from a distance-time graph?
A5: Average speed is calculated by dividing the total distance traveled by the total time taken.
Q6: What is the significance of the slope in a distance-time graph?
A6: The slope represents the speed of the object.
Q7: What does the steepness of the slope in a distance-time graph indicate?
A7: The steepness of the slope indicates the speed; steeper slopes mean higher speeds.
Q8: How does a distance-time graph appear for an object moving with uniform acceleration?
A8: The graph appears as a curve, usually a parabola, representing increasing distance over time.
Q9: What does a zero slope in a distance-time graph indicate?
A9: A zero slope indicates that the object is stationary.
Q10: How can you identify intervals of increasing speed on a distance-time graph?
A10: Intervals of increasing speed are identified by an upward-curving line on the graph.
Velocity-Time Graphs
Q11: What does a horizontal line in a velocity-time graph represent?
A11: It represents uniform velocity with no acceleration.
Q12: How can you find acceleration from a velocity-time graph?
A12: Acceleration is found by the slope of the velocity-time graph.
Q13: What does a positive slope in a velocity-time graph signify?
A13: A positive slope signifies positive acceleration.
Q14: What does a negative slope in a velocity-time graph signify?
A14: A negative slope signifies deceleration or negative acceleration.
Q15: How do you determine the total displacement from a velocity-time graph?
A15: Total displacement is determined by the area under the velocity-time graph.
Q16: What does a straight line with a positive slope on a velocity-time graph indicate?
A16: It indicates uniform acceleration.
Q17: What does a straight line with a negative slope on a velocity-time graph indicate?
A17: It indicates uniform deceleration.
Q18: How does the area under a velocity-time graph relate to motion?
A18: The area under the graph represents the displacement of the object.
Q19: What does a curved line on a velocity-time graph represent?
A19: A curved line represents non-uniform acceleration.
Q20: How can you identify periods of constant velocity on a velocity-time graph?
A20: Periods of constant velocity are shown as horizontal lines on the graph.
General Graphical Representation
Q21: How can you interpret the intersection point of two lines in a distance-time graph?
A21: The intersection point indicates that both objects are at the same position at the same time.
Q22: What is the effect of increasing the gradient of a distance-time graph?
A22: Increasing the gradient means increasing speed.
Q23: How is a graph showing acceleration vs. time usually represented?
A23: It is usually represented as a line where the slope indicates the change in acceleration.
Q24: How does a velocity-time graph change for an object moving with increasing acceleration?
A24: The graph will show a curve with an increasing slope.
Q25: What does the intersection of velocity-time graphs for two objects indicate?
A25: It indicates that the objects have the same velocity at that point in time.
Q26: How is deceleration represented on a velocity-time graph?
A26: Deceleration is represented by a line with a negative slope.
Q27: What does a constant area under the velocity-time graph indicate about an object’s motion?
A27: It indicates that the object is moving with constant velocity.
Q28: What can be inferred from a distance-time graph that shows multiple segments with different slopes?
A28: It indicates that the object’s speed changes at different intervals.
Q29: How can you identify periods of acceleration on a distance-time graph?
A29: Periods of acceleration are shown by curves that become steeper over time.
Q30: What does a decrease in the slope of a distance-time graph indicate?
A30: It indicates a decrease in speed or acceleration.
Complex Graph Analysis
Q31: What does a trapezoid under a velocity-time graph represent?
A31: It represents displacement during the time interval.
Q32: How do you interpret a distance-time graph with multiple segments of different slopes?
A32: Each segment represents a different speed or phase of motion.
Q33: What information does the area between two lines on a velocity-time graph provide?
A33: It provides the relative displacement between two objects.
Q34: How is the total distance traveled represented in a complex distance-time graph?
A34: It is the sum of the distances covered in each segment of the graph.
Q35: What does a velocity-time graph with multiple horizontal lines indicate?
A35: It indicates motion with periods of constant velocity.
Q36: How do you determine the average acceleration from a velocity-time graph?
A36: Average acceleration is calculated as the change in velocity divided by the total time, and can be determined from the slope of the velocity-time graph.
Q37: What does the area under a velocity-time graph with varying slopes represent?
A37: It represents the total displacement with varying acceleration.
Q38: How is the instantaneous velocity read from a velocity-time graph?
A38: It is read as the value of the velocity at a specific point in time on the graph.
Q39: What does a distance-time graph with multiple curves suggest about the motion of an object?
A39: It suggests that the object experiences varying speeds and accelerations.
Q40: How can you analyze the impact of acceleration on displacement from a graph?
A40: By examining the shape and area under the velocity-time graph, you can analyze how acceleration affects displacement.
Additional Graphical Concepts
Q41: What does a zero area under an acceleration-time graph indicate?
A41: It indicates that there is no change in velocity, meaning the object is either at rest or moving with constant velocity.
Q42: How can you determine if an object is accelerating or decelerating from a velocity-time graph?
A42: By looking at the slope of the graph; a positive slope indicates acceleration, and a negative slope indicates deceleration.
Q43: What does a vertical line on a distance-time graph represent?
A43: A vertical line represents an infinite speed, which is not physically possible in realistic scenarios.
Q44: How do you determine the velocity of an object at a specific time from a velocity-time graph?
A44: Velocity at a specific time is given by the value of the graph at that particular time point.
Q45: What does a distance-time graph with decreasing slopes indicate about the object's speed?
A45: It indicates that the object is slowing down.
Q46: How can you interpret the effect of a changing slope in a distance-time graph?
A46: Changing slopes represent varying speeds or accelerations.
Q47: What does a steepening curve in a distance-time graph suggest about acceleration?
A47: It suggests increasing acceleration.
Q48: How do you identify intervals of constant acceleration on a velocity-time graph?
A48: By identifying straight-line segments with a consistent slope.
Q49: How is the total distance covered in different segments of a motion graph calculated?
A49: By summing up the distances represented by each segment of the graph.
Q50: What information can be obtained from a velocity-time graph with multiple sections of different slopes?
A50: It shows that the object experiences varying rates of acceleration.
Q51: How do you determine the instantaneous acceleration from an acceleration-time graph?
A51: By reading the value directly from the graph at a specific time.
Q52: What does the area above the x-axis in an acceleration-time graph represent?
A52: It represents positive acceleration.
Q53: What does the area below the x-axis in an acceleration-time graph represent?
A53: It represents negative acceleration (deceleration).
Q54: How is the displacement during a period of non-uniform acceleration calculated from a velocity-time graph?
A54: By calculating the area under the curve of the velocity-time graph.
Q55: How can you find the total change in velocity from an acceleration-time graph?
A55: By finding the area under the acceleration-time graph.
Q56: What does a horizontal line on an acceleration-time graph indicate?
A56: It indicates constant acceleration.
Q57: How can you determine the object’s speed at a given time using a distance-time graph?
A57: By finding the slope of the graph at that time.
Q58: What does the shape of a velocity-time graph tell you about the object's motion?
A58: The shape indicates whether the object is accelerating, decelerating, or moving at a constant velocity.
Q59: How is the change in velocity represented on a velocity-time graph?
A59: By the slope of the graph.
Q60: How can you identify periods of rest from a velocity-time graph?
A60: By locating the segments where the graph intersects the x-axis.
Advanced Concepts
Q61: How is the concept of relative velocity shown in a velocity-time graph?
A61: Relative velocity can be visualized by comparing the velocity-time graphs of two objects.
Q62: What does the area between two lines in a velocity-time graph represent?
A62: It represents the difference in displacement between two objects.
Q63: How does a constant velocity appear on a distance-time graph compared to a velocity-time graph?
A63: On a distance-time graph, it appears as a straight line with a constant slope; on a velocity-time graph, it appears as a horizontal line.
Q64: How do you find the rate of acceleration from an acceleration-time graph?
A64: By determining the slope of the graph.
Q65: What is the physical significance of the area under an acceleration-time graph?
A65: It represents the change in velocity.
Q66: How can you differentiate between accelerating and decelerating motion from a distance-time graph?
A66: Accelerating motion is shown by a curve with increasing steepness; decelerating motion is shown by a curve with decreasing steepness.
Q67: How is total displacement calculated from a non-uniform acceleration velocity-time graph?
A67: By summing the areas under the graph's curve for each time interval.
Q68: How do you interpret a velocity-time graph with an increasing curve?
A68: An increasing curve indicates increasing acceleration.
Q69: What does a decreasing curve in a distance-time graph suggest about speed?
A69: It suggests that the speed is decreasing.
Q70: How can you determine if an object is moving faster or slower compared to another from their distance-time graphs?
A70: By comparing the slopes of the distance-time graphs; steeper slopes indicate faster motion.
Q71: What information does the slope of a velocity-time graph provide about motion?
A71: It provides information about the rate of change of velocity, i.e., acceleration.
Q72: How does the area under a velocity-time graph represent displacement in varying acceleration scenarios?
A72: The area still represents displacement, but it must be calculated by considering the shape of the area under the curve.
Q73: What is the graphical representation of an object in free fall on a distance-time graph?
A73: It typically shows a curve with increasing steepness due to increasing acceleration.
Q74: How is uniform acceleration shown in a velocity-time graph?
A74: As a straight line with a constant positive slope.
Q75: What does a distance-time graph with multiple straight lines suggest about the object's motion?
A75: It suggests that the object is moving with varying speeds at different intervals.
Q76: How is constant deceleration represented in a velocity-time graph?
A76: As a straight line with a constant negative slope.
Q77: What does the area under a distance-time graph represent in practical terms?
A77: It represents the total distance traveled by the object.
Q78: How can you find instantaneous acceleration from a velocity-time graph?
A78: By finding the slope of the graph at a specific point.
Q79: What does a velocity-time graph with a negative curve indicate about acceleration?
A79: It indicates changing acceleration, where acceleration is decreasing.
Q80: How do you interpret the slope of a line segment in a velocity-time graph?
A80: The slope indicates the acceleration during that time interval.
Q81: What does a curved velocity-time graph suggest about the nature of acceleration?
A81: It suggests that the acceleration is changing over time.
Q82: How do you identify periods of uniform acceleration from a distance-time graph?
A82: By observing parabolic curves which indicate constant acceleration.
Q83: How can you calculate the total time taken for an object to come to rest using a velocity-time graph?
A83: By determining the time at which the velocity becomes zero.
Q84: What does a vertical section on a distance-time graph indicate about the object's speed?
A84: It indicates that the object is moving at an infinite speed, which is theoretically impossible.
Q85: How can you determine if two objects have the same acceleration from their velocity-time graphs?
A85: By comparing the slopes of their respective velocity-time graphs; equal slopes mean equal acceleration.
Q86: What does the shape of a velocity-time graph with multiple segments reveal about an object's motion?
A86: It reveals changes in velocity and acceleration at different intervals.
Q87: How is average velocity calculated from a distance-time graph?
A87: By dividing the total distance traveled by the total time taken.
Q88: What does a distance-time graph with a constant slope indicate about the object's speed?
A88: It indicates that the object is moving with constant speed.
Q89: How do you identify the intervals of negative acceleration from a velocity-time graph?
A89: By finding where the graph slopes downward.
Q90: What information can be derived from the area under a velocity-time graph with irregular shapes?
A90: It provides the total displacement during the time interval.
Q91: How can you determine the time interval during which an object accelerates from a velocity-time graph?
A91: By measuring the length of the segment with a changing slope.
Q92: What does a distance-time graph with a concave curve suggest about the motion?
A92: It suggests accelerating motion.
Q93: How is constant velocity depicted on a distance-time graph?
A93: As a straight line with a constant slope.
Q94: What does the area under a distance-time graph during a specific time interval represent?
A94: It represents the total distance traveled during that interval.
Q95: How do you find the average acceleration from a velocity-time graph with multiple segments?
A95: By calculating the overall change in velocity divided by the total time for all segments.
Q96: How does an increasing slope in a distance-time graph affect the interpretation of motion?
A96: It indicates increasing speed or acceleration.
Q97: What does a decreasing velocity on a velocity-time graph indicate about the object’s motion?
A97: It indicates that the object is decelerating.
Q98: How is an object's motion with varying speed represented on a distance-time graph?
A98: By a curve that changes its steepness over time.
Q99: How can you determine if an object is in uniform motion from a velocity-time graph?
A99: By looking for a horizontal line, which represents constant velocity.
Q100: What does the area between the x-axis and the curve of a velocity-time graph represent?
A100: It represents the displacement of the object.
Q101: How is the total distance traveled represented in a complex distance-time graph?
A101: As the sum of the distances represented by each segment of the graph.
Q102: How do you interpret the velocity of an object at any given time using a velocity-time graph?
A102: By reading the value directly from the graph at that specific time.
Q103: What does a parabolic shape in a distance-time graph suggest about acceleration?
A103: It suggests uniform acceleration.
Q104: How can you find the time required for an object to reach a certain velocity from a velocity-time graph?
A104: By finding the time corresponding to that velocity on the graph.
Q105: What does a velocity-time graph with a flat line above the x-axis indicate?
A105: It indicates a period of constant positive velocity.
Q106: How is the concept of negative velocity represented in a velocity-time graph?
A106: By lines or sections below the x-axis.
Q107: How can you determine periods of zero acceleration from an acceleration-time graph?
A107: By finding flat horizontal sections where the acceleration is constant at zero.
Q108: How is varying speed depicted on a distance-time graph?
A108: By a curve with varying steepness.
Q109: What does a zero slope on a velocity-time graph signify about acceleration?
A109: It signifies that there is no acceleration (constant velocity).
Q110: How can you calculate the total displacement from a complex velocity-time graph?
A110: By calculating the area under the curve for each segment and summing them up.
Q111: How does the area under a distance-time graph relate to the motion of an object?
A111: It represents the total distance traveled over time.
Q112: How do you determine if an object is moving with increasing acceleration from a velocity-time graph?
A112: By observing a curve with increasing slope.
Q113: What does a velocity-time graph with a curved line indicate about the object's acceleration?
A113: It indicates that the acceleration is changing over time.
Q114: How can you interpret the motion of an object from a distance-time graph with multiple segments?
A114: By analyzing each segment to understand the varying speeds during different time intervals.
Q115: What does a horizontal line on an acceleration-time graph represent?
A115: It represents constant acceleration.
Q116: How can you determine the instantaneous velocity from a distance-time graph?
A116: By finding the slope of the tangent to the curve at a specific point.
Q117: What does a decreasing distance-time graph slope suggest about the object's speed?
A117: It suggests that the object's speed is decreasing.
Q118: How is the concept of changing acceleration shown in a velocity-time graph?
A118: By a curve with varying slope.
Q119: How do you calculate the average speed from a distance-time graph with multiple segments?
A119: By dividing the total distance traveled by the total time taken for all segments.
Q120: What does a distance-time graph with an increasing slope indicate about the object's motion?
A120: It indicates that the object is accelerating.
Q121: How can you identify the total displacement from a complex velocity-time graph?
A121: By calculating the area under the curve.
Q122: How do you find the rate of change of acceleration from an acceleration-time graph?
A122: By determining the slope of the graph.
Q123: What does a velocity-time graph with a series of steps indicate about acceleration?
A123: It indicates that acceleration is changing in discrete intervals.
Q124: How can you determine the time it takes for an object to come to rest from a velocity-time graph?
A124: By identifying the time at which the velocity line intersects the x-axis.
Q125: What does a line with a negative slope on a distance-time graph indicate?
A125: It indicates that the object is moving backward or returning to the starting point.
Q126: How is the total distance covered represented in a velocity-time graph with variable acceleration?
A126: By calculating the area under the curve.
Q127: What does a distance-time graph with a consistent gradient reveal about the object's motion?
A127: It reveals constant speed.
Q128: How do you identify periods of negative velocity on a velocity-time graph?
A128: By locating segments where the graph is below the x-axis.
Q129: How is instantaneous acceleration determined from a distance-time graph?
A129: By finding the curvature of the graph at a specific point and calculating the slope of the tangent.
Q130: What does a velocity-time graph with a large area above the x-axis compared to below it suggest?
A130: It suggests that the object has a greater positive displacement compared to negative displacement.
Q131: How do you calculate the total change in velocity from a velocity-time graph with multiple line segments?
A131: By calculating the overall change in velocity across all segments.
Q132: What does the area under a distance-time graph for a specific interval represent?
A132: It represents the total distance traveled during that interval.
Q133: How can you identify uniform motion on a distance-time graph with multiple line segments?
A133: By finding segments with consistent slopes.
Q134: What does a velocity-time graph with a series of straight lines suggest about the object's acceleration?
A134: It suggests that acceleration changes in a stepwise manner.
Q135: How do you find the average velocity from a distance-time graph with non-uniform motion?
A135: By calculating the total distance traveled divided by the total time.
Q136: What does a rapidly increasing curve on a distance-time graph suggest about acceleration?
A136: It suggests that acceleration is increasing.
Q137: How can you determine the object's speed from a distance-time graph with varying slopes?
A137: By measuring the slope of the graph at each segment.
Q138: What does a zero area under an acceleration-time graph signify about the object's motion?
A138: It signifies that there is no change in velocity (constant velocity).
Q139: How is constant speed depicted on a distance-time graph?
A139: As a straight line with a constant positive slope.
Q140: How do you identify varying acceleration from a velocity-time graph?
A140: By analyzing curves with varying slopes.
Q141: What does a distance-time graph with a horizontal section suggest about the object’s motion?
A141: It suggests that the object is at rest during that period.
Q142: How can you find the acceleration from a velocity-time graph with a curved line?
A142: By determining the rate of change of the slope of the graph.
Q143: How is negative acceleration represented in a velocity-time graph?
A143: By a line with a negative slope.
Q144: What does the area between two velocity-time curves represent?
A144: The difference in displacement between two objects.
Q145: How do you determine periods of increasing speed on a distance-time graph?
A145: By identifying the parts of the graph where the curve becomes steeper.
Q146: How is a decreasing speed represented on a distance-time graph?
A146: By a curve that becomes less steep.
Q147: What does a velocity-time graph with a horizontal line below the x-axis indicate?
A147: It indicates negative constant velocity.
Q148: How can you find the average speed from a complex distance-time graph with multiple segments?
A148: By calculating the total distance traveled divided by the total time.
Q149: What does the area under a velocity-time graph with varying slopes represent?
A149: The total displacement, taking into account varying acceleration.
Q150: How is uniform acceleration shown in a distance-time graph?
A150: As a parabolic curve.
Q151: How can you determine the object’s displacement from a distance-time graph with irregular slopes?
A151: By calculating the area under the curve for each segment.
Q152: What does a distance-time graph with a decreasing curve suggest about the object’s motion?
A152: It suggests that the object is slowing down.
Q153: How do you interpret a velocity-time graph with multiple linear segments?
A153: Each segment represents different phases of constant acceleration or deceleration.
Q154: What does a curved section in a velocity-time graph indicate about the object’s acceleration?
A154: It indicates that the acceleration is changing over time.
Q155: How can you determine the average acceleration from a complex acceleration-time graph?
A155: By calculating the overall change in velocity divided by the total time and considering varying acceleration periods.
Q156: How is zero velocity depicted in a distance-time graph?
A156: By a horizontal line at the position corresponding to the zero distance traveled.
Q157: What does a velocity-time graph with a horizontal line at zero velocity indicate?
A157: It indicates a period where the object is at rest.
Q158: How can you determine the rate of change of velocity from a velocity-time graph with a curved line?
A158: By finding the slope of the tangent to the curve at the point of interest.
Q159: How is non-uniform acceleration represented on a distance-time graph?
A159: By a curve with changing steepness.
Q160: What does a steep slope on a velocity-time graph indicate about acceleration?
A160: It indicates a high rate of acceleration.
Q161: How do you interpret a distance-time graph with a horizontal line at increasing distance values?
A161: It indicates that the object is moving with constant speed in the direction of increasing distance.
Q162: What does a rapidly decreasing curve on a distance-time graph indicate about speed?
A162: It indicates that the object is decelerating rapidly.
Q163: How is the concept of instantaneous velocity represented on a distance-time graph with a curve?
A163: By the slope of the tangent line to the curve at a specific point.
Q164: How do you determine the period of acceleration from a distance-time graph?
A164: By identifying segments where the curvature of the graph changes.
Q165: What does a flat line on a velocity-time graph at a value above zero indicate?
A165: It indicates constant positive velocity.
Q166: How is the area under a velocity-time graph used to find displacement in cases of variable acceleration?
A166: By calculating the area under the curve, considering both positive and negative sections.
Q167: How do you interpret a distance-time graph where the slope is continuously increasing?
A167: It suggests that the object is accelerating at an increasing rate.
Q168: What does a decreasing slope in a distance-time graph indicate about acceleration?
A168: It indicates decreasing acceleration or deceleration.
Q169: How is the average acceleration determined from a non-uniform acceleration distance-time graph?
A169: By analyzing the change in velocity over the total time, considering the varying slopes.
Q170: What does the curvature of a velocity-time graph reveal about the object’s acceleration?
A170: It reveals whether the acceleration is increasing or decreasing.
Q171: How do you find the total distance traveled from a distance-time graph with complex curves?
A171: By calculating the area under the curve or summing up the distances from different segments.
Q172: How can you determine the periods of constant velocity from a distance-time graph with irregular slopes?
A172: By identifying segments where the slope remains constant.
Q173: What does a velocity-time graph with a horizontal line below the x-axis suggest about the object’s motion?
A173: It suggests that the object is moving with a constant negative velocity.
Q174: How is varying acceleration depicted on a distance-time graph?
A174: As a curve with varying steepness.
Q175: How do you determine periods of acceleration from a distance-time graph with a parabolic shape?
A175: By identifying sections where the curvature indicates changes in velocity.
Q176: What does a distance-time graph with multiple parabolic curves suggest about the object’s motion?
A176: It suggests that the object undergoes varying acceleration phases.
Q177: How can you find the time taken to reach a certain velocity from a velocity-time graph with a non-linear curve?
A177: By finding the point where the curve reaches the desired velocity and reading the corresponding time.
Q178: What does a steepening curve on a velocity-time graph indicate about acceleration?
A178: It indicates increasing acceleration.
Q179: How do you interpret a distance-time graph with decreasing slopes?
A179: It suggests that the object is decelerating.
Q180: What does the area above the x-axis and below the curve in a velocity-time graph represent?
A180: It represents positive displacement.
Q181: How is negative acceleration represented in a distance-time graph?
A181: By a curve with decreasing steepness.
Q182: How can you calculate the average velocity from a distance-time graph with complex curvature?
A182: By dividing the total distance traveled by the total time.
Q183: What does the total area under a velocity-time graph represent?
A183: The total displacement of the object.
Q184: How do you interpret a distance-time graph with constant steepness?
A184: It indicates uniform motion with constant speed.
Q185: How is the rate of acceleration found from a non-linear velocity-time graph?
A185: By determining the slope of the tangent to the curve at a specific point.
Q186: What does a velocity-time graph with a series of horizontal lines indicate about acceleration?
A186: It indicates periods of constant acceleration or deceleration.
Q187: How do you identify periods of uniform motion from a distance-time graph with multiple slopes?
A187: By finding segments with a constant slope.
Q188: What does a distance-time graph with a horizontal line at increasing distances suggest?
A188: It suggests the object is moving with constant velocity.
Q189: How can you determine the total change in velocity from a complex velocity-time graph?
A189: By summing the changes in velocity across all segments.
Q190: What does a distance-time graph with an increasing slope indicate about the object’s motion?
A190: It indicates increasing speed or acceleration.
Q191: How is uniform acceleration represented on a velocity-time graph?
A191: By a straight line with a constant slope.
Q192: How do you find the average velocity from a distance-time graph with multiple slopes?
A192: By calculating the total distance and dividing it by the total time taken.
Q193: What does a distance-time graph with a curve of decreasing steepness suggest about acceleration?
A193: It suggests that the object is decelerating.
Q194: How is the total distance covered calculated from a complex distance-time graph?
A194: By summing the areas under the curve for each segment.
Q195: What does a distance-time graph with a horizontal section at a low distance suggest about the object’s motion?
A195: It suggests that the object is at rest or moving very slowly during that period.
Q196: How can you interpret the rate of change of velocity from a velocity-time graph with a non-linear curve?
A196: By analyzing the slope of the tangent to the curve at various points.
Q197: What does a distance-time graph with increasing curvature suggest about the object's motion?
A197: It suggests that the object is accelerating at an increasing rate.
Q198: How do you identify uniform acceleration from a velocity-time graph?
A198: By a straight line with a constant positive or negative slope.
Q199: What does a distance-time graph with multiple straight-line segments suggest about the object’s speed?
A199: It suggests that the object changes speed at different intervals.
Q200: How can you find the time required for an object to decelerate to a stop from a velocity-time graph?
A200: By identifying the time when the velocity line intersects the x-axis.
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