Animate a widget using a physics simulation

Physics simulations can make app interactions feel realistic and interactive. For example, you might want to animate a widget to act as if it were attached to a spring or falling with gravity.

This recipe demonstrates how to move a widget from a dragged point back to the center using a spring simulation.

This recipe uses these steps:

  1. Set up an animation controller
  2. Move the widget using gestures
  3. Animate the widget
  4. Calculate the velocity to simulate a springing motion

Step 1: Set up an animation controller

#

Start with a stateful widget called DraggableCard:

dart
import 'package:flutter/material.dart';

void main() {
  runApp(const MaterialApp(home: PhysicsCardDragDemo()));
}

class PhysicsCardDragDemo extends StatelessWidget {
  const PhysicsCardDragDemo({super.key});

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(),
      body: const DraggableCard(
        child: FlutterLogo(
          size: 128,
        ),
      ),
    );
  }
}

class DraggableCard extends StatefulWidget {
  const DraggableCard({required this.child, super.key});

  final Widget child;

  @override
  State<DraggableCard> createState() => _DraggableCardState();
}

class _DraggableCardState extends State<DraggableCard> {
  @override
  void initState() {
    super.initState();
  }

  @override
  void dispose() {
    super.dispose();
  }

  @override
  Widget build(BuildContext context) {
    return Align(
      child: Card(
        child: widget.child,
      ),
    );
  }
}

Make the _DraggableCardState class extend from SingleTickerProviderStateMixin. Then construct an AnimationController in initState and set vsync to this.

dart
class _DraggableCardState extends State<DraggableCard> {
class _DraggableCardState extends State<DraggableCard>
    with SingleTickerProviderStateMixin {
  late AnimationController _controller;

  @override
  void initState() {
    super.initState();
    _controller =
        AnimationController(vsync: this, duration: const Duration(seconds: 1));
  }

  @override
  void dispose() {
    _controller.dispose();
    super.dispose();
  }

Step 2: Move the widget using gestures

#

Make the widget move when it's dragged, and add an Alignment field to the _DraggableCardState class:

dart
class _DraggableCardState extends State<DraggableCard>
    with SingleTickerProviderStateMixin {
  late AnimationController _controller;
  Alignment _dragAlignment = Alignment.center;

Add a GestureDetector that handles the onPanDown, onPanUpdate, and onPanEnd callbacks. To adjust the alignment, use a MediaQuery to get the size of the widget, and divide by 2. (This converts units of "pixels dragged" to coordinates that Align uses.) Then, set the Align widget's alignment to _dragAlignment:

dart
@override
Widget build(BuildContext context) {
  return Align(
    child: Card(
      child: widget.child,
  var size = MediaQuery.of(context).size;
  return GestureDetector(
    onPanDown: (details) {},
    onPanUpdate: (details) {
      setState(() {
        _dragAlignment += Alignment(
          details.delta.dx / (size.width / 2),
          details.delta.dy / (size.height / 2),
        );
      });
    },
    onPanEnd: (details) {},
    child: Align(
      alignment: _dragAlignment,
      child: Card(
        child: widget.child,
      ),
    ),
  );
}

Step 3: Animate the widget

#

When the widget is released, it should spring back to the center.

Add an Animation<Alignment> field and an _runAnimation method. This method defines a Tween that interpolates between the point the widget was dragged to, to the point in the center.

dart
class _DraggableCardState extends State<DraggableCard>
    with SingleTickerProviderStateMixin {
  late AnimationController _controller;
  late Animation<Alignment> _animation;
  Alignment _dragAlignment = Alignment.center;
dart
void _runAnimation() {
  _animation = _controller.drive(
    AlignmentTween(
      begin: _dragAlignment,
      end: Alignment.center,
    ),
  );
  _controller.reset();
  _controller.forward();
}

Next, update _dragAlignment when the AnimationController produces a value:

dart
@override
void initState() {
  super.initState();
  _controller =
      AnimationController(vsync: this, duration: const Duration(seconds: 1));
  _controller.addListener(() {
    setState(() {
      _dragAlignment = _animation.value;
    });
  });
}

Next, make the Align widget use the _dragAlignment field:

dart
child: Align(
  alignment: _dragAlignment,
  child: Card(
    child: widget.child,
  ),
),

Finally, update the GestureDetector to manage the animation controller:

dart
return GestureDetector(
  onPanDown: (details) {},
  onPanDown: (details) {
    _controller.stop();
  },
  onPanUpdate: (details) {
    // ...
  },
  onPanEnd: (details) {},
  onPanEnd: (details) {
    _runAnimation();
  },
  child: Align(

Step 4: Calculate the velocity to simulate a springing motion

#

The last step is to do a little math, to calculate the velocity of the widget after it's finished being dragged. This is so that the widget realistically continues at that speed before being snapped back. (The _runAnimation method already sets the direction by setting the animation's start and end alignment.)

First, import the physics package:

dart
import 'package:flutter/physics.dart';

The onPanEnd callback provides a DragEndDetails object. This object provides the velocity of the pointer when it stopped contacting the screen. The velocity is in pixels per second, but the Align widget doesn't use pixels. It uses coordinate values between [-1.0, -1.0] and [1.0, 1.0], where [0.0, 0.0] represents the center. The size calculated in step 2 is used to convert pixels to coordinate values in this range.

Finally, AnimationController has an animateWith() method that can be given a SpringSimulation:

dart
/// Calculates and runs a [SpringSimulation].
void _runAnimation(Offset pixelsPerSecond, Size size) {
  _animation = _controller.drive(
    AlignmentTween(
      begin: _dragAlignment,
      end: Alignment.center,
    ),
  );
  // Calculate the velocity relative to the unit interval, [0,1],
  // used by the animation controller.
  final unitsPerSecondX = pixelsPerSecond.dx / size.width;
  final unitsPerSecondY = pixelsPerSecond.dy / size.height;
  final unitsPerSecond = Offset(unitsPerSecondX, unitsPerSecondY);
  final unitVelocity = unitsPerSecond.distance;

  const spring = SpringDescription(
    mass: 30,
    stiffness: 1,
    damping: 1,
  );

  final simulation = SpringSimulation(spring, 0, 1, -unitVelocity);

  _controller.animateWith(simulation);
}

Don't forget to call _runAnimation() with the velocity and size:

dart
onPanEnd: (details) {
  _runAnimation(details.velocity.pixelsPerSecond, size);
},

Interactive Example

#
import 'package:flutter/material.dart';
import 'package:flutter/physics.dart';

void main() {
  runApp(const MaterialApp(home: PhysicsCardDragDemo()));
}

class PhysicsCardDragDemo extends StatelessWidget {
  const PhysicsCardDragDemo({super.key});

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(),
      body: const DraggableCard(
        child: FlutterLogo(
          size: 128,
        ),
      ),
    );
  }
}

/// A draggable card that moves back to [Alignment.center] when it's
/// released.
class DraggableCard extends StatefulWidget {
  const DraggableCard({required this.child, super.key});

  final Widget child;

  @override
  State<DraggableCard> createState() => _DraggableCardState();
}

class _DraggableCardState extends State<DraggableCard>
    with SingleTickerProviderStateMixin {
  late AnimationController _controller;

  /// The alignment of the card as it is dragged or being animated.
  ///
  /// While the card is being dragged, this value is set to the values computed
  /// in the GestureDetector onPanUpdate callback. If the animation is running,
  /// this value is set to the value of the [_animation].
  Alignment _dragAlignment = Alignment.center;

  late Animation<Alignment> _animation;

  /// Calculates and runs a [SpringSimulation].
  void _runAnimation(Offset pixelsPerSecond, Size size) {
    _animation = _controller.drive(
      AlignmentTween(
        begin: _dragAlignment,
        end: Alignment.center,
      ),
    );
    // Calculate the velocity relative to the unit interval, [0,1],
    // used by the animation controller.
    final unitsPerSecondX = pixelsPerSecond.dx / size.width;
    final unitsPerSecondY = pixelsPerSecond.dy / size.height;
    final unitsPerSecond = Offset(unitsPerSecondX, unitsPerSecondY);
    final unitVelocity = unitsPerSecond.distance;

    const spring = SpringDescription(
      mass: 30,
      stiffness: 1,
      damping: 1,
    );

    final simulation = SpringSimulation(spring, 0, 1, -unitVelocity);

    _controller.animateWith(simulation);
  }

  @override
  void initState() {
    super.initState();
    _controller = AnimationController(vsync: this);

    _controller.addListener(() {
      setState(() {
        _dragAlignment = _animation.value;
      });
    });
  }

  @override
  void dispose() {
    _controller.dispose();
    super.dispose();
  }

  @override
  Widget build(BuildContext context) {
    final size = MediaQuery.of(context).size;
    return GestureDetector(
      onPanDown: (details) {
        _controller.stop();
      },
      onPanUpdate: (details) {
        setState(() {
          _dragAlignment += Alignment(
            details.delta.dx / (size.width / 2),
            details.delta.dy / (size.height / 2),
          );
        });
      },
      onPanEnd: (details) {
        _runAnimation(details.velocity.pixelsPerSecond, size);
      },
      child: Align(
        alignment: _dragAlignment,
        child: Card(
          child: widget.child,
        ),
      ),
    );
  }
}