MIT scientists might be one step closer to making insulin injections a thing of the past. In a new study this week, they’ve shown that it’s possible to implant a medical device inside mice that produces its own supply of insulin for up to a month. More research will be needed before this technology would be widely available to use in humans, however.

The team’s device features a membrane that creates oxygen by splitting apart nearby water molecules—in theory, allowing for an indefinite supply of oxygen. The device can also be powered wirelessly with a small amount of voltage, which might only require a small patch to be worn on the skin.

See https://gizmodo.com/mit-scientists-device-makes-insulin-injections-obsolete-1850852945

#technology #medical #health #diabetes

MIT scientists might be one step closer to making insulin injections a thing of the past. In a new study this week, they’ve shown that it’s possible to implant a medical device inside mice that produces its own supply of insulin for up to a month. More research will be needed before this technology would be widely available to use in humans, however.

The team’s device features a membrane that creates oxygen by splitting apart nearby water molecules—in theory, allowing for an indefinite supply of oxygen. The device can also be powered wirelessly with a small amount of voltage, which might only require a small patch to be worn on the skin.

See https://gizmodo.com/mit-scientists-device-makes-insulin-injections-obsolete-1850852945

#technology #medical #health #diabetes

MIT scientists might be one step closer to making insulin injections a thing of the past. In a new study this week, they’ve shown that it’s possible to implant a medical device inside mice that produces its own supply of insulin for up to a month. More research will be needed before this technology would be widely available to use in humans, however.

The team’s device features a membrane that creates oxygen by splitting apart nearby water molecules—in theory, allowing for an indefinite supply of oxygen. The device can also be powered wirelessly with a small amount of voltage, which might only require a small patch to be worn on the skin.

See https://gizmodo.com/mit-scientists-device-makes-insulin-injections-obsolete-1850852945

#technology #medical #health #diabetes

Yes, you could use a AirTag or similar, but this is LTE-M enabled with a SIM and full GPS, and it powers down into an idle mode while the pet is at home. It ends up having a 6-month battery life.

The collar is built around a Nordic Semiconductor NRF-9160, a System in a Package (SiP) that does most of the heavy lifting as it includes GPS, an LTE-M modem, and an ARM processor. One interesting feature here: [Sahas] doesn’t make his antennas on the PCB, but instead uses an Ignion NN03-310, an off-the-shelf antenna that is already qualified for LTE-M use. That means this system can be connected to almost any LTE-M network without getting yelled at for using unqualified hardware and making the local cell towers explode.

As one commentator says, it is really well documented and designed, and looks much like a product designed by Apple themselves. So, an iOS app is expected, but there are no plans to produce an Android app, although the dev says he is open to someone from the community creating one.

See https://hackaday.com/2023/09/19/open-source-tracker-keeps-an-eye-on-furry-friends/

#technology #trackers #pets

Yes, you could use a AirTag or similar, but this is LTE-M enabled with a SIM and full GPS, and it powers down into an idle mode while the pet is at home. It ends up having a 6-month battery life.

The collar is built around a Nordic Semiconductor NRF-9160, a System in a Package (SiP) that does most of the heavy lifting as it includes GPS, an LTE-M modem, and an ARM processor. One interesting feature here: [Sahas] doesn’t make his antennas on the PCB, but instead uses an Ignion NN03-310, an off-the-shelf antenna that is already qualified for LTE-M use. That means this system can be connected to almost any LTE-M network without getting yelled at for using unqualified hardware and making the local cell towers explode.

As one commentator says, it is really well documented and designed, and looks much like a product designed by Apple themselves. So, an iOS app is expected, but there are no plans to produce an Android app, although the dev says he is open to someone from the community creating one.

See https://hackaday.com/2023/09/19/open-source-tracker-keeps-an-eye-on-furry-friends/

#technology #trackers #pets

Yes, you could use a AirTag or similar, but this is LTE-M enabled with a SIM and full GPS, and it powers down into an idle mode while the pet is at home. It ends up having a 6-month battery life.

The collar is built around a Nordic Semiconductor NRF-9160, a System in a Package (SiP) that does most of the heavy lifting as it includes GPS, an LTE-M modem, and an ARM processor. One interesting feature here: [Sahas] doesn’t make his antennas on the PCB, but instead uses an Ignion NN03-310, an off-the-shelf antenna that is already qualified for LTE-M use. That means this system can be connected to almost any LTE-M network without getting yelled at for using unqualified hardware and making the local cell towers explode.

As one commentator says, it is really well documented and designed, and looks much like a product designed by Apple themselves. So, an iOS app is expected, but there are no plans to produce an Android app, although the dev says he is open to someone from the community creating one.

See https://hackaday.com/2023/09/19/open-source-tracker-keeps-an-eye-on-furry-friends/

#technology #trackers #pets

About two months ago we got woken in the middle of the night to the UPS system alarm screaming, and pitch darkness. The UPS keeps the Internet router alive, with the main solar system powering that. This should not happen as my solar system runs on a Lithium battery, and I have 24/7 audible alerts if the battery gets down to 20% for any reason. That night the battery was on around 37% if I remember correctly, and suddenly just shut off.

South Africa has had its heaviest load shedding this year, but even so, I always allow a good safety margin of 5+ hours on battery to cater for the odd 4-hour load shedding stages. So, this was really odd. But after speaking to the installers, they told me that as it was in the middle of Winter, I had been running my battery for weeks down to 30% or so, and it was never achieving a full 100% charge during those weeks. What had happened was, the State of Charge (SOC) % was no longer accurate as the battery needs a full charge into 100% until it reaches idle mode, to balance out the cells. With the imbalance, that 37% SOC showing was in fact the hard cut-off of the actual 10% average SOC that was reached = hard shut down. I also have the battery set to not preserve battery life (which would normally adjust the minimum SOC upwards, until a day where the battery charges fully).

The solution is quite simple: At least once a week, I should ensure the battery is fully charged, whether by solar or grid power. But how do you check that?

I monitor tons of metrics off the solar system already, including down to what tomorrow's solar energy forecast is, the cloud cover for the next day, etc. So, this week I thought, why not write an automation to restart a timer every time the battery reaches a full charge, and warn me if this reaches 7 days, to do a full charge?

I already post the code for this home automation to a GitHub project repo, but I thought this time, let me actually open a discussion thread on the repo, so I could chat to myself as I went through the process. This will prove more useful for me next time I need to troubleshoot it, and also would help anyone else wanting to implement it (instead of trying to figure out all the separate bits of commented code).

The basics are working now, but before I upload the actual code changes, I'm just letting it run a bit to be sure that the warnings work, and that the timer does reset properly at full charge (its trigger checks for battery status changing from charging to idle, at 100% SOC). If there is some cell imbalance, the charging normally continues at 100% for a good 10 minutes or longer, and this needs to be allowed for.

I'm still pondering a bit around maybe automating the full charge process. There are two or three ways of doing it, but I also don't want to waste grid power if I know the next day is going to be a good solar energy day. So possibly I can have HA look at the forecast for the following day, and if low, then charge fully from say 15:00, and switch back to normal usage mode.

See https://github.com/Danie10/gadgeteerza-homeassistant/discussions/6

#technology #Victron #HomeAssistant #opensource

About two months ago we got woken in the middle of the night to the UPS system alarm screaming, and pitch darkness. The UPS keeps the Internet router alive, with the main solar system powering that. This should not happen as my solar system runs on a Lithium battery, and I have 24/7 audible alerts if the battery gets down to 20% for any reason. That night the battery was on around 37% if I remember correctly, and suddenly just shut off.

South Africa has had its heaviest load shedding this year, but even so, I always allow a good safety margin of 5+ hours on battery to cater for the odd 4-hour load shedding stages. So, this was really odd. But after speaking to the installers, they told me that as it was in the middle of Winter, I had been running my battery for weeks down to 30% or so, and it was never achieving a full 100% charge during those weeks. What had happened was, the State of Charge (SOC) % was no longer accurate as the battery needs a full charge into 100% until it reaches idle mode, to balance out the cells. With the imbalance, that 37% SOC showing was in fact the hard cut-off of the actual 10% average SOC that was reached = hard shut down. I also have the battery set to not preserve battery life (which would normally adjust the minimum SOC upwards, until a day where the battery charges fully).

The solution is quite simple: At least once a week, I should ensure the battery is fully charged, whether by solar or grid power. But how do you check that?

I monitor tons of metrics off the solar system already, including down to what tomorrow's solar energy forecast is, the cloud cover for the next day, etc. So, this week I thought, why not write an automation to restart a timer every time the battery reaches a full charge, and warn me if this reaches 7 days, to do a full charge?

I already post the code for this home automation to a GitHub project repo, but I thought this time, let me actually open a discussion thread on the repo, so I could chat to myself as I went through the process. This will prove more useful for me next time I need to troubleshoot it, and also would help anyone else wanting to implement it (instead of trying to figure out all the separate bits of commented code).

The basics are working now, but before I upload the actual code changes, I'm just letting it run a bit to be sure that the warnings work, and that the timer does reset properly at full charge (its trigger checks for battery status changing from charging to idle, at 100% SOC). If there is some cell imbalance, the charging normally continues at 100% for a good 10 minutes or longer, and this needs to be allowed for.

I'm still pondering a bit around maybe automating the full charge process. There are two or three ways of doing it, but I also don't want to waste grid power if I know the next day is going to be a good solar energy day. So possibly I can have HA look at the forecast for the following day, and if low, then charge fully from say 15:00, and switch back to normal usage mode.

See https://github.com/Danie10/gadgeteerza-homeassistant/discussions/6

#technology #Victron #HomeAssistant #opensource

About two months ago we got woken in the middle of the night to the UPS system alarm screaming, and pitch darkness. The UPS keeps the Internet router alive, with the main solar system powering that. This should not happen as my solar system runs on a Lithium battery, and I have 24/7 audible alerts if the battery gets down to 20% for any reason. That night the battery was on around 37% if I remember correctly, and suddenly just shut off.

South Africa has had its heaviest load shedding this year, but even so, I always allow a good safety margin of 5+ hours on battery to cater for the odd 4-hour load shedding stages. So, this was really odd. But after speaking to the installers, they told me that as it was in the middle of Winter, I had been running my battery for weeks down to 30% or so, and it was never achieving a full 100% charge during those weeks. What had happened was, the State of Charge (SOC) % was no longer accurate as the battery needs a full charge into 100% until it reaches idle mode, to balance out the cells. With the imbalance, that 37% SOC showing was in fact the hard cut-off of the actual 10% average SOC that was reached = hard shut down. I also have the battery set to not preserve battery life (which would normally adjust the minimum SOC upwards, until a day where the battery charges fully).

The solution is quite simple: At least once a week, I should ensure the battery is fully charged, whether by solar or grid power. But how do you check that?

I monitor tons of metrics off the solar system already, including down to what tomorrow's solar energy forecast is, the cloud cover for the next day, etc. So, this week I thought, why not write an automation to restart a timer every time the battery reaches a full charge, and warn me if this reaches 7 days, to do a full charge?

I already post the code for this home automation to a GitHub project repo, but I thought this time, let me actually open a discussion thread on the repo, so I could chat to myself as I went through the process. This will prove more useful for me next time I need to troubleshoot it, and also would help anyone else wanting to implement it (instead of trying to figure out all the separate bits of commented code).

The basics are working now, but before I upload the actual code changes, I'm just letting it run a bit to be sure that the warnings work, and that the timer does reset properly at full charge (its trigger checks for battery status changing from charging to idle, at 100% SOC). If there is some cell imbalance, the charging normally continues at 100% for a good 10 minutes or longer, and this needs to be allowed for.

I'm still pondering a bit around maybe automating the full charge process. There are two or three ways of doing it, but I also don't want to waste grid power if I know the next day is going to be a good solar energy day. So possibly I can have HA look at the forecast for the following day, and if low, then charge fully from say 15:00, and switch back to normal usage mode.

See https://github.com/Danie10/gadgeteerza-homeassistant/discussions/6

#technology #Victron #HomeAssistant #opensource