The model may be implicit, but it’s embedded in the structure of the whole thermostat system, from the thermometer that measures temperature to the heating and cooling systems that it controls. For instance, it “knows” that turning on the heat is the appropriate thing to do when the temperature it reads falls below its set point. There is an implication there that the heater causes temperature to rise, or that the AC causes it to fall, even though it’s obviously not running simulations (unless it’s a really good thermostat) on how the heating/cooling systems affect the dynamics of temperature fluctuations in the building.
The engineers did all the modeling beforehand, then built the thermostat to activate the heating and cooling systems in response to temperature fluctuations according to the rules that they precomputed. Evolution did just this in building the structure of the amoeba’s gene networks and the suite of human instincts (heritable variation + natural selection is how information is transferred from the environment into a species’ genome). Lived experience pushes further information from the environment to the internal model, upregulating or downregulating various genes in response to stimuli or learning to reinforce certain behaviors in certain contexts. But environmental information was already there in the structure to begin with, just like it is in more traditional artificial control systems.
The example with the hunter and pheasants was just to show how “regulating” (i.e., consistently achieving a state in the desirable set = pheasant successfully shot) requires the hunter to have a good mental model of the system (pheasant behavior, wind disturbances, etc.). Again, this model does not have to be explicit in general but could be completely innate.
I can’t match any of that up to Conant and Ashby’s paper, though.
As you say, the engineers designing a thermostat have a model of the system. But the thermostat does not. It simply compares the temperature with that set on the dial and turns a switch on and off. There is no trace of any model, prediction, expectation, knowledge of what its actions do, and so on. The engineers do have these things, the proof of which is that you can elicit their knowledge. The thermostat does not, the proof of which is that nowhere in the thermostat can any of these things be found.
The hunter is an obscure example, because no-one knows how humans accomplish such things, and instead we mostly make up stories based on what the process feels like from within. This method has a poor track record. More illuminating would be to look at a similar but man-made system: an automatic anti-aircraft gun shooting at a plane. Whether the control systems inside this device contain models is an empirical question, to be answered by looking at how it works. Maybe it does, and maybe it doesn’t. There is such a thing as model-based control, and there is such a thing as PID controllers (which do not contain models).
The model may be implicit, but it’s embedded in the structure of the whole thermostat system, from the thermometer that measures temperature to the heating and cooling systems that it controls. For instance, it “knows” that turning on the heat is the appropriate thing to do when the temperature it reads falls below its set point. There is an implication there that the heater causes temperature to rise, or that the AC causes it to fall, even though it’s obviously not running simulations (unless it’s a really good thermostat) on how the heating/cooling systems affect the dynamics of temperature fluctuations in the building.
The engineers did all the modeling beforehand, then built the thermostat to activate the heating and cooling systems in response to temperature fluctuations according to the rules that they precomputed. Evolution did just this in building the structure of the amoeba’s gene networks and the suite of human instincts (heritable variation + natural selection is how information is transferred from the environment into a species’ genome). Lived experience pushes further information from the environment to the internal model, upregulating or downregulating various genes in response to stimuli or learning to reinforce certain behaviors in certain contexts. But environmental information was already there in the structure to begin with, just like it is in more traditional artificial control systems.
The example with the hunter and pheasants was just to show how “regulating” (i.e., consistently achieving a state in the desirable set = pheasant successfully shot) requires the hunter to have a good mental model of the system (pheasant behavior, wind disturbances, etc.). Again, this model does not have to be explicit in general but could be completely innate.
I can’t match any of that up to Conant and Ashby’s paper, though.
As you say, the engineers designing a thermostat have a model of the system. But the thermostat does not. It simply compares the temperature with that set on the dial and turns a switch on and off. There is no trace of any model, prediction, expectation, knowledge of what its actions do, and so on. The engineers do have these things, the proof of which is that you can elicit their knowledge. The thermostat does not, the proof of which is that nowhere in the thermostat can any of these things be found.
The hunter is an obscure example, because no-one knows how humans accomplish such things, and instead we mostly make up stories based on what the process feels like from within. This method has a poor track record. More illuminating would be to look at a similar but man-made system: an automatic anti-aircraft gun shooting at a plane. Whether the control systems inside this device contain models is an empirical question, to be answered by looking at how it works. Maybe it does, and maybe it doesn’t. There is such a thing as model-based control, and there is such a thing as PID controllers (which do not contain models).