Why emotions cannot be assigned numbers?

In summary, the conversation discussed the concept of more or less and how it can be applied to both numbers and emotions. It was noted that while numbers have specific values and can be easily compared, emotions are more subjective and cannot be reduced to a simple number. The idea of using scales to measure emotions was also brought up, but it was acknowledged that it may not be possible to have a universal scale that applies to all individuals. The conversation also touched on the importance of having a consistent definition of units of measurement, as well as the limitations of scales in accurately measuring certain phenomena.
  • #1
Avichal
295
0
Okay, this might be a weird question and I am not sure which sub-forum it belongs to - Math, biology or here.

We have this concept of more or less. Given two quantities, we can see whether they are equal, more or less. So we assign each quantity some number, symbol to address it.

Similarly with emotions like love, hatred we can say whether somebody love the person more or less compared to other. Although it's subjective, we have this more or less concept for emotions too.
 
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  • #2
Numbers are robustly defined, singular, and reduced. Emotions are vaguely defined, degenerate, and emergent.
 
  • #3
We do, its just that the number assigned is not necessarily an objective number and should be taken with a grain of salt. We have things like pain scales (for pain, obviously), ratings of perceived exertion (RPE) etc. A quick Google search reveals examples of emotional scales. They are efforts to quantify subjective experiences so doing comparisons is not as simple as say, weighing something and saying that it is 1kg.

As far as I know, these scales are not really based on a standard (such as distance is, for example) and lack precision (you won't see people asking for a rating of 2.344 for example). They do however, aid in therapeutic settings where progress measurement is important. For instance, you can be a 5/10 for pain today and a 3/10 for pain tomorrow and that would indicate to your therapist that you are on the right track. The therapist probably wouldn't tell you that you are 40% better just because of those two numbers.
 
  • #4
Avichal said:
Okay, this might be a weird question and I am not sure which sub-forum it belongs to - Math, biology or here.

This is a topic mostly concerning classification of psychological phenomenon so it fits in biology best. The medical sciences sub forum is for topics related to disease/injury, treatments and medical specific research,

Avichal said:
We have this concept of more or less. Given two quantities, we can see whether they are equal, more or less. So we assign each quantity some number, symbol to address it.

Similarly with emotions like love, hatred we can say whether somebody love the person more or less compared to other. Although it's subjective, we have this more or less concept for emotions too.

Essentially what Pyth said but ill add that even though we could give a rating to our emotions (e.g 1-10 how much do you love X where 1 is slightly more than liking and 10 is head over the heals obsessed) it would be almost entirely arbitrary and subjective with no utility. A complex opinion or feeling can't be reduced to a simple number.
 
  • #5
It is a matter of finding a ruler. No ruler, no value, no comparison.
 
  • #6
The Weber-Fechner law for perception is, in the case of perceiving weight, typically based on that the "just noticeable difference between two waits, so that if you can only just distinguish between a 100g and 105g weight, the "just noticable difference" has increased to 10 grams if the lighter weight weighs 200 grams.

Several other perception-types "sort of" follow such perception laws.
http://en.wikipedia.org/wiki/Weber–Fechner_law
---
This has very little to do with quantifying "love" or other emotions, however.
 
  • #7
People are irrational as well. For example when asked questions about how happy people were in relationships, 8 months later asked questions about previous answers, if the relationship had changed, 78% of men and 87% of women inaccurately recalled how they used to feel.

Lots of experiments have been done where there are other factors you can manipulate to change responses but surprisingly in predictable ways which kinda in some ways contradicts other assertions to the original question.
 
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  • #8
Today, a unit of measurement is thought to need the same definition across the world. If the past a foot meant different things in England and France and there are still differences between an American gallon and an English gallon. Another example is the Richter Scale which couldn't accurately rate some earthquakes. It still managed to scale most earthquakes accurately.

Maybe one of the hurdles preventing the use of scales to measure emotions is the idea that they need to apply to every human being. If one can come up with a unit of measurement for emotions that fit the data for even one person it would be worthwhile and might lead to other useful research.
 
  • #9
TheAbsoluTurk said:
Today, a unit of measurement is thought to need the same definition across the world. If the past a foot meant different things in England and France and there are still differences between an American gallon and an English gallon. Another example is the Richter Scale which couldn't accurately rate some earthquakes. It still managed to scale most earthquakes accurately.
All of these things can be measured in some form, so can be compared.

Maybe one of the hurdles preventing the use of scales to measure emotions is the idea that they need to apply to every human being. If one can come up with a unit of measurement for emotions that fit the data for even one person it would be worthwhile and might lead to other useful research.
I personally do not believe that emotions can ever be meaningfully measured because the same situation can be experienced with incredible differences between each person.
 
  • #10
Avichal said:
We have this concept of more or less. Given two quantities, we can see whether they are equal, more or less. So we assign each quantity some number, symbol to address it.

Similarly with emotions like love, hatred we can say whether somebody love the person more or less compared to other. Although it's subjective, we have this more or less concept for emotions too.
When you talk about two quantities being seen as equal, more or less and assigning some value to something, I think you must be thinking of objectively observable phenomena such as temperature, density, or the magnitude of an electrical charge for example. We can pick out some objectively observable phenomenon and assign a value to it that's a function of some feature the phenomenon exhibits. Once we measure something we can assign a value to. Then we can all measure it in some similar way and agree to that value.

The problem with emotions is that they are subjective, not objective properties. Only the person experiencing the emotion can say anything about them. We can objectively observe the person's neurons interacting for example, but we can't assign a value to the experience they are having that we can't measure. Subjective phenomena are like that, they can't be objectively measured. I think that's the fundamental problem.
 
  • #11
I think emotions and a lot of other experiences could be quantified with more sensitive, non-invasive EEG's.

Here's an EEG of a man having a deja vu accompanied by illusion of precognition, which is exactly the kind of simple partial seizure I have:

firstbatch.jpg


Seeing this EEG completely explained to me why this experience is so persuasive. While I am having one of these I am convinced I have lived through the moment before and am not at liberty to question it. This EEG shows why: the neural activity is through the roof. The strength of the subjective experience correlates with the strength of the neural activity.

This EEG required an invasive depth-implanted electrode. I believe if we could get such readings non-invasively everyone's emotions could be read and their strength quantified. We could, conceivably, determine who loves who more, etc.
 
  • #12
Deja vu for many people don't have any special feelings involved, they're a just a fleeting sense of something feeling like it's happened before, but may not be emotional at all. The ones I've had were simply, "oh, I could swear I've seen this building before", but there was zero emotion connected to it.

People that have emotions tied to relationships, for example, cannot be, IMO, quantified, because just as the real relationship had highs and lows, so do the memories. Also, the same memory today can be more or less intense as the same memory another time, depending on your mood and what triggered the memory.
 
  • #13
Evo said:
Deja vu for many people don't have any special feelings involved, they're a just a fleeting sense of something feeling like it's happened before, but may not be emotional at all. The ones I've had were simply, "oh, I could swear I've seen this building before", but there was zero emotion connected to it.
The "feeling" of familiarity is the emotion in question. People don't think of familiarity as an emotion that's internally generated. They tend to ascribe familiarity to things in the external world as a property of those things. But it isn't. The phenomena of Deja Vu, Jamais Vu, and Capgras Syndrome, demonstrate that "familiarity" is a subjectively experienced emotion, and not a property inherent in external things. A certain kind of damage to your amygdala and being confronted by something as familiar as your parents won't trigger the least feeling of familiarity in you.

An EEG of the mild "fleeting" sensation you describe would not look anything like the above posted EEG, I'm sure. Regardless, activity of some intensity would be recorded from your temporal lobes, no mental event happens without neuronal activity, and could be given a place on a scale: quantified.

People that have emotions tied to relationships, for example, cannot be, IMO, quantified, because just as the real relationship had highs and lows, so do the memories. Also, the same memory today can be more or less intense as the same memory another time, depending on your mood and what triggered the memory.
The fact the intensity of emotion linked to something specific changes over time wouldn't prevent you from quantifying it at any given time. Any specific emotion could, in principle, be quantified at the time of testing if we could non-invasively sample activity in specific locations in the temporal lobes.

For a broader picture: your bank account total today is probably not the same it was a week ago. Regardless, money is one of the most eminently quantifiable things we have. There's plenty of math tools for dealing with quantities that change over time. All you need to get started is the ability to quantify a thing at a given time.

Mostly what I meant by that remark about "who loved who most" though, is that it would be easy, with this tool, to figure out which of two people generally experiences more intense emotions and place your bet on them.
 
  • #14
So if we find a ruler, say something like brain signals when a person experiences love then can we assign numbers to that emotion?
 
  • #15
For one, I doubt emotions are isolated so well and second, because of degeneracy, two different neural systems can result in the same function. So there's going to be a lot of ambiguity between subjects.

I think a ruler is theoretically possible, but not practically. And you'd have to accept generalizations (though we already do that when classifying things in science).
 
  • #16
May I state for the record that I believe emotions can and will one day be quantified in terms of equations: they're still all neural impulses albeit quite complex. We just do not in my opinion understand both the brain and mathematics well enough to do it yet. But I realize reducing the lovely emotion of love for example to a raw set of mathematical equations might seem to take away some of the allure of this human phenomenon, and so some may abhor the notion of such.

I am very optimistic one day after I am gone, we will unlock the secrets of mind and consciousness and construct artificial minds modeled closely to the human brain and these will have phenomena which resemble human emotions like love and hate, and that these artificial emotions will be understood within the context of their construction: the underlying architecture and dynamics. Those dynamics will in turn, be describable by mathematics.
 
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  • #17
Avichal said:
Okay, this might be a weird question and I am not sure which sub-forum it belongs to - Math, biology or here.

We have this concept of more or less. Given two quantities, we can see whether they are equal, more or less. So we assign each quantity some number, symbol to address it.

Similarly with emotions like love, hatred we can say whether somebody love the person more or less compared to other. Although it's subjective, we have this more or less concept for emotions too.

Psychology does use numerical scales, often by using a Likert scale as a probe. Other numerical scales include IQ, lie scales, anxiety scales, and MMPI (Minnesota Multiphasic Personality Inventory).
 
  • #18
Pythagorean said:
For one, I doubt emotions are isolated so well...
Depends on what you mean by this. If you're saying that something like "pure" love, or hate, or fear, never happens in isolation from other emotions, of course I agree. We usually experience a range of several simultaneous emotions. I think, though, that it should eventually be possible to isolate the nuclei that are responsible for any specific one. When you say that two different neural systems can result in the same function, I suspect there's actually a difference between the two functions produced by two different neural systems, however subtle. Analogy: a cello, a viola, and a violin all overlap in the range of pitches they can produce. And, listening to a string quartette I certainly cannot always tell which instrument is producing which pitch. An electronic analyzer performing an ongoing Fourier analysis, though, could probably always distinguish one instrument from the other. If all you had was recordings of quartettes with no knowledge of the different instruments they comprise, the invention of that analyzer would have to precede the knowledge that there were three similar, but not exactly the same, instruments producing the "string" sounds.

Hopefully that's relevant to what you said, but I might not have correctly caught your drift.

I think a ruler is theoretically possible, but not practically. And you'd have to accept generalizations (though we already do that when classifying things in science).
I think the SQUID represents our first efforts at creating the kind of "ruler" we'd need:

The extreme sensitivity of SQUIDs makes them ideal for studies in biology. Magnetoencephalography (MEG), for example, uses measurements from an array of SQUIDs to make inferences about neural activity inside brains. Because SQUIDs can operate at acquisition rates much higher than the highest temporal frequency of interest in the signals emitted by the brain (kHz), MEG achieves good temporal resolution.

http://en.wikipedia.org/wiki/SQUID

I have no idea what it would take to move from "inferences" to confident "measurements", but it seems people have been working on this for some decades now.

Anyway, I think there is rock solid, hard data there, we just can't get to it to measure it. If and when we can, there would still have to be a lot of generalization, as you said. Ultimately, emotion should become at least as quantifiable as, say, a weather system is now.
 
  • #19
"When you say that two different neural systems can result in the same function, I suspect there's actually a difference between the two functions produced by two different neural systems, however subtle."

Subtle differences would be swamped by noise and variation from specimen to specimen, so they would effectively be the same even if the degeneracy weren't perfect.

However, they're quite literally the same output signal. You can setup a system where the output neuron looks exactly the same for several different underlying networks. If that one neuron is the only point of interface, than any neuron downstream from it won't be able to tell what the underlying network was that produced the output of that neuron. That's where degeneracy lies in neural signaling.

Of course, you can come up with an emotion system that avoids degeneracy, but it would be speculative. Functionality in neurons is, indeed, degenerate, so if you wanted to base emotions on function (measurable observables) you'd have to justify why emotions aren't degenerate and I'm fairly sure our understanding of the neural correlates of emotions is still quite primitive in this regard.
 
  • #20
Pythagorean said:
Of course, you can come up with an emotion system that avoids degeneracy, but it would be speculative. Functionality in neurons is, indeed, degenerate, so if you wanted to base emotions on function (measurable observables) you'd have to justify why emotions aren't degenerate and I'm fairly sure our understanding of the neural correlates of emotions is still quite primitive in this regard.
I'm not sure what goal you would set for the quantification of emotion, but my idea was simply that the intensity of emotions could be quantified based on the premise that the intensity of the experience is directly proportional to the intensity of the neuronal activity generating the experience. I don't think degeneracy, as you explain it, needs to be addressed at all for that. It seems to me a simple matter of being able to measure amplitude and frequency of, for example, a specific nucleus in the amygdala that's correlated with a specific emotional experience.
 
  • #21
zoobyshoe said:
It seems to me a simple matter of being able to measure amplitude and frequency of, for example, a specific nucleus in the amygdala that's correlated with a specific emotional experience.

To a certain extent you can, but degeneracies are even still a problem. Functions are distributed across many nuclei and there's overlap in functionality between different nuclei, so local measurements will almost always suffer from degeneracy problems. There's additional qualitative ambiguities too:

Different pain experiences are characterized by different patterns of supraspinal activation.
For example, noxious chemical stimuli infrequently evoke activation of the parietal operculum whereas noxious thermal stimuli produce robust activation of this structure (20). Similarly, some forms of chronic pain evoke a paradoxical asymmetric decrease in thalamic blood flow whereas the majority of acute pain states are characterized by contralateral or bilateral increases in the activation of this region (20, 26, 27). Thus,
generalizations between different pain states may be misleading. Pain is defined by the first-person experiential perspective and must be diagnosed and treated with significant consideration of the subjective report. Thus, even if unique patterns of brain activity have been characterized in large numbers of patients for a given chronic pain state, the subjective report will likely remain the single most reliable index of the magnitude of pain.
Importantly, the present findings validate the subjective report and provide insight into the utility of introspection as a means of assessing a conscious experience. First-person introspection is a necessary component of the process of generating a subjective report for communication to a third-person observer. Therefore,
the finding that individuals with similar patterns of activation of SI, ACC, and PFC provided similar subjective reports of pain magnitude suggests that they can accurately capture their conscious experience via introspection

http://www.pnas.org/content/100/14/8538.full.pdf+html
 
  • #22
I really don't see the point.

Let's say I'm asked to rate an event from 1 - 10, with 10 being the worst, I say it's a 10. Another person is asked to rate the "same" event on a scale of 1 - 10 and they say it's a 5. A third person rates it a 3, another person rates it a 6. Is there actually any point to this? How do we know that the same event is felt the same? How do we rate the answers? Even if you are looking at real time brain scans, which person's rating is real? If one is a psychopath, how would their ratings appear? Different people will respond differently to the same experience. Their brains will respond differently, there is no way of comparing.

You can't say, "oh we'll look at the brain scans", that's meaningless since different brains respond differently to the same stimulus.
 
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  • #23
The point is usually to reduce pain or use pain to diagnose symptoms in health settings. The absolute scores aren't compared, but if a group of people consistently lower their scores beyond placebo in response to a drug, then your painkiller has passed one more test.
 
  • #24
Pythagorean said:
The point is usually to reduce pain or use pain to diagnose symptoms in health settings. The absolute scores aren't compared, but if a group of people consistently lower their scores beyond placebo in response to a drug, then your painkiller has passed one more test.
Yes, I'd agree on rating responses to drugs such as pain killers, but I was thinking more along the lines of rating responses to varied emotional situations, such as a break up, the person being dumped.
 
  • #25
Pythagorean said:
To a certain extent you can, but degeneracies are even still a problem. Functions are distributed across many nuclei and there's overlap in functionality between different nuclei, so local measurements will almost always suffer from degeneracy problems. There's additional qualitative ambiguities too:

http://www.pnas.org/content/100/14/8538.full.pdf+html
I'm a bit confused about your point. I didn't read the whole paper scrupulously, but it seems to support my position. Once the subjects were trained to be introspective enough to characterize their pain articulately, their reports turned out to correlate well with the scans:

"Therefore, the finding that individuals with similar patterns of activation of SI, ACC, and PFC provided similar subjective reports of pain magnitude suggests that they can accurately capture their conscious experience via introspection."

The point of the paper seems to be to prove we can gather objective data that verifies the reliability of subjective reports of pain. Therefore, subjective reports of pain can be trusted.

Having done that, the experimenters ought to be able to proceed to take a scan, look at it, and now predict what the subjects will say about their pain. (This wasn't their goal, but it follows from the results they obtained.)

That being the case, the same thing should be able to be done with emotion. A scan would reveal what activates to what degree when a subject says he is feeling, say, anger of level 6 on a 1-10 scale. It would be found, as you say, that different nuclei would be involved to different degrees, depending on the specific 'shade and flavor' of anger, because, like pain, anger's not a monocoque, one dimensional experience. But, having thus calibrated the measurement, they should be able to proceed to take the scan first, then accurately predict what the subject will report about the intensity and quality of their anger.
 
  • #26
no, what it says is the brain scans aren't robust and that the subjective report takes precedence. You only need to read what I quoted (more carefully).
 
  • #27
Numbers define quantities, emotions quantify priorities in the natural sense.
 
  • #28
Pythagorean said:
no, what it says is the brain scans aren't robust and that the subjective report takes precedence. You only need to read what I quoted (more carefully).
I've reread it 5 times and get the same meaning out of it. They were able to see marked differences in the scans of individuals who reported that the pain was more intense. This is summed up in the section titled "Discussion".

This study is absolutely saying that the scans are good, and objectively prove the mentioned areas are more active in subjects who give the pain a higher rating. In other words, it objectively validates the self-reporting of patients with regard to pain intensity.
 
  • #29
You're possibly conflating forward inference with backward inference. This is an important consideration, especially in brain imaging. It has been explicitly research and published about:

http://www.sciencedirect.com/science/article/pii/S1364661305003360
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3240863/

In general, anytime you have a conditional, you shouldn't automatically assume the converse of the conditional is true, forward/reverse inference is the statistical analog of this. A simple example is that when you kick a ball, it's likely the ball moves, but every time the ball moves doesn't imply that it's equally likely it was kicked.

Specifically, I agree that A --> B (the study implies, through brain states, that subjective states are reliable) but they very explicitly mention that B -/-> A (subjective state reports do not imply a particular brain state). And this is exactly what degeneracy is. Degeneracy is an accepted fact of biological systems in general, and is especially applicable to the problem of forward vs. reverse inference in brain imaging.

I'll narrow down the previous quote for you so you can see where respect to the above is paid in the paper:

"Thus, generalizations between different pain states may be misleading. Pain is defined by the first-person experiential perspective and must be diagnosed and treated with significant consideration of the subjective report. Thus, even if unique patterns of brain activity have been characterized in large numbers of patients for a given chronic pain state, the subjective report will likely remain the single most reliable index of the magnitude of pain."

(other than that the whole tone of the paper is that subjective reports are more reliable than brain imaging when you read it in full)

More on degeneracy in general in biological systems:
http://www.pnas.org/content/96/6/3257.short
http://www.pnas.org/content/98/24/13763.short

if you want to play with forward inference vs. backward inference, here's a meta-analysis tool for imaging studies. In imaging, you don't trust just one study in the first place, statistical confidence is generally weak, and that is the motivation behind this tool, but you also get to explicitly see how direction of inference affects the answer to your questions:
http://neurosynth.org/explore [Broken]

You can read their FAQ about the specific difference of their particular instance of forward vs. reverse inference (and even posterior) here too:
http://old.neurosynth.org/faqs#faq8

It's not the general case of forward/reverse inference, but it's related.
 
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  • #30
also, let's not forget that this report was for pain, which is much easier to characterize (both subjectively and objectively) than emotions.
 
  • #31
Upon continued re-reading I keep coming to the conclusion this paper is asserting patient reports are reliable because they verified it with brain scans!

It does not say brain scans are unreliable. Brain scans are what they used to verify the reliability of patient reports.

The part you quoted in bold warns about generalizing over kinds of pain, while remaining confident about pain magnitude.

The title of the paper is, "Neural correlates of interindividual differences in the subjective experience of pain." They found those titular neural correlates. With brain scans. They got different brain scans for people reporting different levels of pain in response to the same stimulus. Certain brain areas were much more active in the individuals reporting more intense pain in response to the same stimulus.

If we're not in agreement about this basic point, that they confirmed the reliability of patient reports with brain scans, and by no other means, then there's no point in branching off into the other topics you introduced.
 
  • #32
Pythagorean said:
also, let's not forget that this report was for pain, which is much easier to characterize (both subjectively and objectively) than emotions.
But the OP is about emotions, not pain.

So we need to get back on topic please.
 

1. Why can't emotions be measured and quantified like other scientific data?

Emotions are complex and subjective experiences that cannot be reduced to numbers. They involve a combination of physiological responses, cognitive processes, and individual perceptions, making it difficult to assign a numerical value to them.

2. Can't emotions be measured using brain scans or other scientific techniques?

While brain scans and other scientific techniques can provide insight into the physiological processes associated with emotions, they cannot accurately measure the subjective experience of an emotion. Emotions are influenced by a variety of factors and cannot be reduced to a single brain activity or physical response.

3. How do we know if someone is experiencing a certain emotion if we can't assign a number to it?

Emotions can be expressed and recognized through non-verbal cues, such as facial expressions, body language, and tone of voice. These cues can provide insight into a person's emotional state, but they do not represent a quantitative measure of that emotion.

4. Why do we need to assign numbers to emotions in the first place?

Assigning numbers to emotions is often seen as a way to make them more understandable and controllable. However, emotions are a natural and necessary part of being human, and trying to quantify them can oversimplify and devalue their complexity.

5. Is there any benefit to trying to measure emotions numerically?

While emotions cannot be accurately measured using numbers, studying and understanding them can still provide valuable insights. By focusing on the underlying processes and factors that influence emotions, we can gain a deeper understanding of how they impact our thoughts, behaviors, and overall well-being.

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