# What does hysteresis mean and how does it apply to computer science or programming?

I was looking at some code and saw an out of context comment about 'hysteresis.' I think I have figured out what the code does so my question doesn't involve anything specific. I simply do not understand what the term means or how it is applicable in programming. I looked around and saw some mathmatic definitions but would like some more information. From what I can tell Hysteresis has something to do with predicting or assuming a given state for X based on what has happened to X in the past?

-
First, include the definition you found. It helps to know what definitions you've read so far. We don't want to repeat stuff. – S.Lott Mar 18 '11 at 21:18

Hysteresis characterizes a system whose behavior (output) does not only depend on its input at time t, but also on its past behavior, on the path it has followed.

A well-known device that exhibits hysteresis is a thermostat. Imagine a thermostat that would switch on and off heating at 70°F. When temperature is around 70°F, while fluctuating a bit, the thermostat would continually switch heating on and off. Generally, a thermostat is built with hysteresis: it will switch on heating at (say) 69°F, but switch off heating at 71°F. This avoids the continual switches.

EDIT: have a look at Wikipedia's article.

-

Good answers. In practical integration layers, this is very important. An integration layer with hysteresis is itself a subsystem. Clearly, the ideal is no hysteresis (a Moore machine); but, typically there is a mismatch in the state machines of each of the systems and this can only be solved by a translator using hysteresis. For instance, Microsoft Dynamics/Great Plains Field Service module records state in its SVC00210 Service Master Audit Trail table. Each Call is in some SRVSTAT. When integrating a scheduler like ClickSoftware's service optimization scheduler then one needs to work with its state. The state of CS is determined by the custom implementation. E.g. Open, InRoute, OnSite, Incomplete, Cancelled, Complete. Additionally, it also has a state of Incomplete with Parts Pending although this is implemented as a sub- State Machine within Incomplete. So, transitions in GP must be mapped into CS. Unfortunately, GP allows (does record on screen input for a call) transitions from one state to itself; so, thus, the transition event cannot be used solely for triggering the state change in GP. Therefore, the new trigger event is a combination of the GP state transition as well as a meta-state defined by some logic on the set of past events. As you can see, hysteresis quickly takes the problem from simple to complex. In computer science terms the ideal is a Moore Machine but the practical is the Mealy Machine. I prefer to think of it like Mealy flour with bugs living in it and all! I think its possible to produce a Moore machine from any Mealy machine, the Moore machine will simply have more states. See: Mealy v/s. Moore

-

Thermostat example:

``````heatPointLow = 8°C
heatPointHeight = 10°C
heater = off

while(true){
if(temperature < heatPointLow)
heater = on
if(temperature > heatPointHeight)
heater = off
}
``````

If there where just one point the system coul'd oscillate around that single point. Between the points height and low it depends on the last value of the heater if it is on or off.

-