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Silová pole

Force Fields offer a way to add extra movement to dynamic systems. Particles, Soft Bodies, Rigid Bodies and Cloth objects can all be affected by forces fields. Force Fields automatically affect everything. To remove a simulation or particle system from their influence, simply turn down the influence of that type of Force Field in its Field Weights panel.

  • Všechny typy objektů a částic mohou tvořit silová pole, ?but only curve object can ?bear Curve Guides pole.
  • Silová pole mohou být generovány částicemi. Viz Fyzika částic
  • Objekty potřebují sdílet alespoň jednu společnou vrstvu pro to, aby byl jev patrný.

Je možné omezit efekt na částice na skupinu objektů. Více na stránce Fyzika částic.

Vytvoření silového pole

Mód: Object Mode

Panel: Object kontext → Physics-fyzika podkontext → Fields-pole

Klávesová zkratka: F7

Pro vytvoření jednoduchého silového pole vyberte Add » Force Field a vyberte požadovaný typ pole. Tato metoda vytvoří objekt Empty (prázdné) s připojeným silovým polem.

Pro vytvoření silového pole z existujícího objektu musíte vybrat objekt a změnit jeho fyzikální podkontext. Vyberte typ pole v menu Fields.

Pole mají mnoho nastavení a běžně se dají vysvětlit na sférickém (Spherical) poli.


After changing the fields (Fields panel) or deflection (Collision panel) settings, you have to recalculate the particle, softbody or cloth system (Free Cache), this is not done automatically. You can clear the cache for all selected objects with CtrlB → Free cache selected.

Particles react to all kind of Force Fields, Soft Bodies only to Spherical/Wind/Vortex (they react on Harmonic fields but not in a useful way).

Common Field Settings

Most Fields have the same settings, even though they act very differently. Settings unique to a field type are described below. Curve Guide and Texture Fields have very different options.

The field is either a Point, with omnidirectional influence, or a Plane, constant in the XY-plane, changes only in Z direction.
The strength of the field effect. This can be positive or negative to change the direction that the force operates in. A force field’s strength is scaled with the force object’s scale, allowing you to scale up and down scene, keeping the same effects.
Convert effector force into air flow velocity.
Adds noise to the strength of the force.
Changes the seed of the random noise.
Effect Point
You can toggle the field's effect on particle Location and Rotation
Collision Absorption
Force gets absorbed by collision objects.


Here you can specify the shape of the force field (if the Fall-off Power is greater than 0).

Falloff is uniform in all directions, as in a sphere.
Fall off results in a tube shaped force field.
The Field's Radial falloff can be adjusted, as well as the Minimum and Maximum distances of the field.
Fall off results in a cone shaped force field. Additional options are the same as those of Tube options.
Z Direction
Fall-off can be set to apply only in the direction of the positive Z Axis, negative Z Axis, or both.
Power (Power)
How the power of the force field changes with the distance from the force field. If r is the distance from the center of the object, the force changes with 1/rPower. A Fall-off of 2 changes the force field with 1/r2, which is the falloff of gravitational pull.
Max Distance - maximální vzdálenost
Makes the force field only take effect within a specified maximum radius (shown by an additional circle around the object).
Min Distance
The distance from the object center, up to where the force field is effective with full strength. If you have a Fall-off of 0 this parameter does nothing, because the field is effective with full strength up to Max Dist (or the infinity). Shown by an additional circle around the object.

Typy polí


The Force field is the simplest of the fields. It gives a constant force towards (positive strength) or away from (negative strength) the object’s center. Newtonian particles are attracted to a field with negative strength, and are blown away from a field with positive strength.

For Boids a field with positive strength can be used as a Goal, a field with negative strength can be used as Predator. Whether Boids seek or fly goals/predators depends on the Physics settings of the Boids.

Image 2b: Spherical field indicator.


Image 3a: Wind field indicator.

Wind gives a constant force in a single direction, along the force object’s local Z axis. The strength of the force is visualized by the spacing of the circles shown.


Image 3b: Vortex field indicator.

Vortex fields give a spiraling force that twists the direction of points around the force object’s local Z axis. This can be useful for making a swirling sink, or tornado, or kinks in particle hair.


This field depends on the speed of the particles. It simulates the force of magnetism on magnetized objects.


The source of the force field is the zero point of a harmonic oscillator (spring, pendulum). If you set the Damping parameter to 1, the movement is stopped in the moment the object is reached. This force field is really special if you assign it to particles.

Rest Length
Controls the rest length of the harmonic force.
Multiple Springs
Causes every point to be affected by multiple springs.

Normally every particle of the field system influences every particle of the target system. Not with Harmonic! Here every target particle is assigned to a field particle. So particles will move to the place of other particles, thus forming shapes. Tutorial: Particles forming Shapes.


It is similar to spherical field except it changes behavior (attract/repulse) based on the effected particles charge field (negative/positive), like real particles with a charge. This mean this field has only effect on particles that have also a Charge field (else, they have no “charge”, and hence are unaffected)!


Toto pole je velice krátkodosahové a dosahuje jak odpudivé pro menší vzdálenosti, tak odpudivých charakteristik pro vzdálenosti větší. Toto pole má snahu držet částice v rovnovážné vzdálenosti (equilibrium distance) jedna od druhé. Obvykle se tyto síly kombinují se síly dané rozdílným nábojem.

Particles can have for example both a charge and a Lennard-Jones potential - which is probably something for the nuclear physicists amongst us.

Pole textur

You can use a texture force field to create an arbitrarily complicated force field, which force in the 3 directions is color coded. Red is coding for the x-axis, green for the y-axis and blue for the z-axis (like the color of the coordinate axes in the 3D window). A value of 0.5 means no force, a value larger than 0.5 acceleration in negative axis direction (like -Z), a value smaller than 0.5 acceleration in positive axis direction (like +Z).

Texture mode
This sets the way a force vector is derived from the texture.
Uses the color components directly as the force vector components in the color encoded directions. You need an RGB texture for this, e.g. an image or a colorband. So a Blend texture without a colorband would not suffice.
Calculates the force vector as the 3d-gradient of the intensity (grayscale) of the texture. The gradient vector always points to the direction of increasing brightness.
Calculates the force vector from the curl of the 3d-rgb texture (rotation of rgb vectors). This also works only with a color texture. It can be used for example to create a nice looking turbulence force with a color clouds texture with perlin noise.
It is the offset used to calculate the partial derivatives needed for Gradient and Curl texture modes.
Use Object Coordinates
Uses the emitter object coordinates (and rotation & scale) as the texture space the particles use. Allows for moving force fields, that have their coordinates bound to the location coordinates of an object.
Root Texture Coordinates
This is useful for hair as it uses the texture force calculated for the particle root position for all parts of the hair strand.
The 2D button disregards the particles z-coordinate and only uses particles x&y as the texture coordinates.

Remember that only procedural texture are truly 3D.


  • A single colored texture 0.5/0.0/0.5 creates a force in the direction of the positive y-axis, e.g. hair is orientated to the y-axis.
  • A blend texture with colorband can be used to created a force “plane”. E.g. on the left side 0.5/0.5/0.5, on the right side 1.0/0.5/0.5 you have a force plane perpendicular to XY (i.e. parallel to Z). If you use an object for the coordinates, you can use the object to push particles around.
  • An animated wood texture can be used to create a wave like motion.

Curve Guide

Image 4a: A Curve Guide field.

Curve objects can be the source of a Curve Guide field. You can guide particles along a certain path, they don’t affect Softbodys. A typical scenario would be to move a red blood cell inside a vein, or to animate the particle flow in a motor. You can use Curve Guides also to shape certain hair strands - though this may no longer be used as often now because we have the Particle Mode. Since you can animate curves as Softbody or any other usual way, you may build very complex animations while keeping great control and keeping the simulation time to a minimum.

The option Curve Follow does not work for particles. Instead you have to set Angular Velocity (in the Physics panel of the Particle sub-context) to Spin and leave the rotation constant (i.e. don’t turn on Dynamic).

Curve Guides affect all particles on the same layer, independently from their distance to the curve. If you have several guides in a layer, their fields add up to each other (the way you may have learned it in your physics course). But you can limit their influence radius:

Minimum Distance
The distance from the curve, up to where the force field is effective with full strength. If you have a Fall-off of 0 this parameter does nothing, because the field is effective with full strength up to MaxDist (or the infinity). MinDist is shown with a circle at the endpoints of the curve in the 3D window.

Fraction of particle life time, that is not used for the curve.
This setting governs the strength of the guide between MinDist and MaxDist. A Fall-off of 1 means a linear progression.

A particle follows a Curve Guide during it’s lifetime, the velocity depends from it’s lifetime and the length of the path.

If you use Additive, the speed of the particles is also evaluated depending on the Fall-off.
Use Curve weights to influence the particle influence along the curve.
Maximum Distance/Use Max
The maximum influence radius. Shown by an additional circle around the curve object.

The other settings govern the form of the force field along the curve.

Clumping Amount
The particles come together at the end of the curve (1) or they drift apart (-1).
Defines the form in which the particles come together. +0.99: the particles meet at the end of the curve. 0: linear progression along the curve. -0.99: the particles meet at the beginning of the curve.
Image 4b: Kink options of a curve guide. From left to right: Radial, Wave, Braid, Roll.

With the drop down box Kink, you can vary the form of the force field:

The radius of the influence depends on the distance of the curve to the emitter.
A three dimensional, standing wave.
A two dimensional, standing wave.
A one dimensional, standing wave.

It is not so easy to describe the resulting shapes, I hope it’s shown clearly enough in (Image 4b).

The frequency of the offset.
Adjust the offset to the beginning/end.
The Amplitude of the offset.


Název Boid pochází z počítačového programu vyvinutého Craigem Reynoldsem v roce 1986. Program simuluje chování letu ptáků. Jeho práce na toto téma byla publikována v roce 1987 ve sborníku konference ACM SIGGRAPH. Stejně jako u většiny simulací umělého života je Boids příkladem důležitého chování. Složitost Boids vyplývá ze vzájemného ovlivňování jednotlivých prvků (dále boids v tomto případě ) podchycené sadou jednoduchých pravidel. Pravidla uplatňovaná v nejjednodušším prostředí Boids jsou následující:

  • oddělení, separace - prvky se chovají tak, aby nevytěšňovaly sousední
  • zarovnání - směr pohybu se v průměru blíží k prvním letcům
  • soudržnost, koheze - pohyb prvků směřuje tak, že průměrné místní těžiště místních prvků se nemění.

Samozřejmě mohou být přidána k chování "Boids" daleko složitější další pravidla.


Create a random turbulence effect with a 3d noise.

Indicates the scale of the noise.
Makes the size and strength of the noise relative to the world, instead of the object it is attached to.

Tažení, brždění

Drag is a force that works to resist particle motion by slowing it down.

Drag component proportional to velocity.
Drag component proportional to the square of the velocity.