I've purged a lot of the knowledge from that time from my brain, but from what I recall fNIRS takes a long time (on the order of multiple seconds) to take a single reading.
It also only really shows which regions of the brain are receiving more blood supply. While a huge improvement in spacial precision over EEG, it's still not anywhere near the same level of precision that a directly-wired nerve has.
That doesn't mean it's useless technology, just probably not viable for the low-latency, high-accuracy control you'd want for a military drone.
>Another question: is it possible to do ah molecular identification similar to idk quantum crystallography with photons of any wavelength, such as NIRS? Could that count things in samples?
I have absolutely no idea about molecular identification or quantum crystallography, so probably can't give you a good answer on that one.
IIUC, they're shooting for realtime MRI resolution with NIRS; to be used during surgery to assist surgery in realtime.
edit: https://en.wikipedia.org/wiki/Neural_oscillation#Overview says brainwaves are 1-150 Hz? IIRC compassion is acheivable on a bass guitar.
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4049706/
Retracted: https://journals.plos.org/plosbiology/article?id=10.1371/jou...
Table with resolution differences between different techniques:
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8116487/table/T...
It's also noteworthy that you're dealing with huge amounts of noise, very low resolution, and are limited to the cortical surface. This limits the applications in the BCI-domain.
I'm currently researching the feasability of fast optical imaging. This has to be done in the frequency domain, but may yield temporal resolution in the milliseconds. The downside is finding an incoherent light source that's able to be modulated fast enough to detect the scattering changes.
From https://twitter.com/westurner/status/1049860034899927040 :
https://web.archive.org/web/20171003175149/https://www.omnis...
"Mind Control and EM Wave Polarization Transductions" (1999)
> To engineer the mind and its operations directly, one must perform electrodynamic engineering in the time * domain, not in the 3-space EM energy density domain.*
Could be something there.
Topological Axion antiferromagnet https://phys.org/news/2021-07-layer-hall-effect-2d-topologic... :
> Researchers believe that when it is fully understood, TAI can be used to make semiconductors with potential applications in electronic devices, Ma said. The highly unusual properties of Axions will support a new electromagnetic response called the topological magneto-electric effect, paving the way for realizing ultra-sensitive, ultrafast, and dissipationless sensors, detectors and memory devices.
Optical topological antennas https://engineering.berkeley.edu/news/2021/02/light-unbound-... :
> The new work, reported in a paper published Feb. 25 in the journal Nature Physics, throws wide open the amount of information that can be multiplexed, or simultaneously transmitted, by a coherent light source. A common example of multiplexing is the transmission of multiple telephone calls over a single wire, but there had been fundamental limits to the number of coherent twisted light waves that could be directly multiplexed.
Rydberg sensor https://phys.org/news/2021-02-quantum-entire-radio-frequency... :
> Army researchers built the quantum sensor, which can sample the radio-frequency spectrum—from zero frequency up to 20 GHz—and detect AM and FM radio, Bluetooth, Wi-Fi and other communication signals.
> The Rydberg sensor uses laser beams to create highly-excited Rydberg atoms directly above a microwave circuit, to boost and hone in on the portion of the spectrum being measured. The Rydberg atoms are sensitive to the circuit's voltage, enabling the device to be used as a sensitive probe for the wide range of signals in the RF spectrum.
> "All previous demonstrations of Rydberg atomic sensors have only been able to sense small and specific regions of the RF spectrum, but our sensor now operates continuously over a wide frequency range for the first time,"
The xMed Exponential Medicine conference / program is in November this year: https://twitter.com/ExponentialMed
Space medicine also presents unique constraints that more rigorously select from possible solutions: https://en.wikipedia.org/wiki/Space_medicine
There is no progress in medicine without volunteers for clinical research trials. https://en.wikipedia.org/wiki/Phases_of_clinical_research
> Below are examples of the image quality we have achieved with our breakthrough scanning systems that use just red and near-infrared light and ultrasound pings.
https://en.wikipedia.org/wiki/Near-infrared_spectroscopy
Another question: is it possible to do ah molecular identification similar to idk quantum crystallography with photons of any wavelength, such as NIRS? Could that count things in samples?
https://twitter.com/westurner/status/1239012387367387138 :
> ... quantum crystallography: https://en.wikipedia.org/wiki/Quantum_crystallography There's probably some limit to infrared crystallography that anyone who knows anything about particles and lattices would know about ?