Meanwhile, my Wi-Fi router requires a PhD in reverse engineering just to figure out why it won’t connect to the internet.

I do think people in general could benefit from maybe $100 in tools and a healthy dose of Youtube when it comes to this point. My PC of 10 years wouldn't boot one morning because my SSD died. There wasn't anything too important on it that I hadn't backed up, but it was still a bummer. I took it apart, and started poking around. Found a short across a capacitor, so I started cycling capacitors. Sure enough, one was bad. Replaced it. Boots just fine. (Moved everything to a new SSD just in case).

All I needed for this job was a multimeter and a soldering iron (though hot air gun made it slightly easier).

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

Yet there's zero expectation of user maintenance. If it doesn't work, trash it.

Scroll through maker TikTok

This guy might be looking in the wrong places.

Meanwhile, my Wi-Fi router requires a PhD in reverse engineering just to figure out why it won’t connect to the internet.

I do think people in general could benefit from maybe $100 in tools and a healthy dose of Youtube when it comes to this point. My PC of 10 years wouldn't boot one morning because my SSD died. There wasn't anything too important on it that I hadn't backed up, but it was still a bummer. I took it apart, and started poking around. Found a short across a capacitor, so I started cycling capacitors. Sure enough, one was bad. Replaced it. Boots just fine. (Moved everything to a new SSD just in case).

All I needed for this job was a multimeter and a soldering iron (though hot air gun made it slightly easier).

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

Yet there's zero expectation of user maintenance. If it doesn't work, trash it.

Scroll through maker TikTok

This guy might be looking in the wrong places.

Meanwhile, my Wi-Fi router requires a PhD in reverse engineering just to figure out why it won’t connect to the internet.

I do think people in general could benefit from maybe $100 in tools and a healthy dose of Youtube when it comes to this point. My PC of 10 years wouldn't boot one morning because my SSD died. There wasn't anything too important on it that I hadn't backed up, but it was still a bummer. I took it apart, and started poking around. Found a short across a capacitor, so I started cycling capacitors. Sure enough, one was bad. Replaced it. Boots just fine. (Moved everything to a new SSD just in case).

All I needed for this job was a multimeter and a soldering iron (though hot air gun made it slightly easier).

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

Yet there's zero expectation of user maintenance. If it doesn't work, trash it.

Scroll through maker TikTok

This guy might be looking in the wrong places.

Meanwhile, my Wi-Fi router requires a PhD in reverse engineering just to figure out why it won’t connect to the internet.

I do think people in general could benefit from maybe $100 in tools and a healthy dose of Youtube when it comes to this point. My PC of 10 years wouldn't boot one morning because my SSD died. There wasn't anything too important on it that I hadn't backed up, but it was still a bummer. I took it apart, and started poking around. Found a short across a capacitor, so I started cycling capacitors. Sure enough, one was bad. Replaced it. Boots just fine. (Moved everything to a new SSD just in case).

All I needed for this job was a multimeter and a soldering iron (though hot air gun made it slightly easier).

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

Yet there's zero expectation of user maintenance. If it doesn't work, trash it.

Scroll through maker TikTok

This guy might be looking in the wrong places.

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

This is a symptom of industry switching to cheap "disposable" electronics, rather than more expensive, robust, and repairable ones.

From the treadmill company's point of view, it's cheaper to just lose one unit and pay shipping one way rather than pay to have the unit returned, spend valuable technician time diagnosing and fixing an issue and then pay to ship the repaired unit back.

About 50 years ago, you could find appliance repair shops that would fix your broken toaster or TV, and parts for stuff like that were easily available. Now, with the advanced automation in building these, combined with the increased difficulty of repair(fine-work soldering, firmware debuging and the like) it makes way more sense to just replace the whole thing.

Meanwhile, my Wi-Fi router requires a PhD in reverse engineering just to figure out why it won’t connect to the internet.

I do think people in general could benefit from maybe $100 in tools and a healthy dose of Youtube when it comes to this point. My PC of 10 years wouldn't boot one morning because my SSD died. There wasn't anything too important on it that I hadn't backed up, but it was still a bummer. I took it apart, and started poking around. Found a short across a capacitor, so I started cycling capacitors. Sure enough, one was bad. Replaced it. Boots just fine. (Moved everything to a new SSD just in case).

All I needed for this job was a multimeter and a soldering iron (though hot air gun made it slightly easier).

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

Yet there's zero expectation of user maintenance. If it doesn't work, trash it.

Scroll through maker TikTok

This guy might be looking in the wrong places.

There are real limits to repairability in modern devices, some placed there just in order to force you to pay the manufacturer more money. But you're right that there's a lot we could do that we're just not bothering to do.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

My buddy has a $6000 projector. He found it in the trash. The only thing wrong with it was a cracked solder on the power supply.

Similarly, I have a $5000 audio console that I got for ~$100 in parts; it had a bad power supply. Honestly, probably just a bad capacitor on the power supply, but I didn’t feel like desoldering every capacitor to check their capacitance. Diagnosing the power supply took about 5 minutes, and most of that was just finding all of the screws that were holding the case together. A quick read with a multimeter told me everything I needed to know. Swapped out the supply, and it has been working fine ever since.

pay to have the unit returned, spend valuable technician time diagnosing and fixing an issue and then pay to ship the repaired unit back.

My point is that in a better world, people could fix this kind of thing themselves. Like offer a discount for their trouble and have them or their mechanic aunt come by and fix it.

Meanwhile, my Wi-Fi router requires a PhD in reverse engineering just to figure out why it won’t connect to the internet.

I do think people in general could benefit from maybe $100 in tools and a healthy dose of Youtube when it comes to this point. My PC of 10 years wouldn't boot one morning because my SSD died. There wasn't anything too important on it that I hadn't backed up, but it was still a bummer. I took it apart, and started poking around. Found a short across a capacitor, so I started cycling capacitors. Sure enough, one was bad. Replaced it. Boots just fine. (Moved everything to a new SSD just in case).

All I needed for this job was a multimeter and a soldering iron (though hot air gun made it slightly easier).

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

Yet there's zero expectation of user maintenance. If it doesn't work, trash it.

Scroll through maker TikTok

This guy might be looking in the wrong places.

eh. give me schematics. i can't fix anything beyond trivial issues without it.

then it won't be as much of a black box.

beyond trivial issues

I'd argue that 10-15% of issues are trivial issues and are worth investigating even without a schematic if the alternative is just throwing something away.

I think the "black box" nature of electronics is mostly illusory due to how we treat our devices. A friend bought a walking treadmill that wouldn't turn on out of the box. She contacted the company, they told her to trash it and just shipped her a new one.

She gave it to me, I took it apart. One of the headers that connects the power switch to the mainboard was just unplugged. It took literally 10 minutes to "fix" including disassembly and assembly, and all I needed was a screwdriver.

This is a symptom of industry switching to cheap "disposable" electronics, rather than more expensive, robust, and repairable ones.

From the treadmill company's point of view, it's cheaper to just lose one unit and pay shipping one way rather than pay to have the unit returned, spend valuable technician time diagnosing and fixing an issue and then pay to ship the repaired unit back.

About 50 years ago, you could find appliance repair shops that would fix your broken toaster or TV, and parts for stuff like that were easily available. Now, with the advanced automation in building these, combined with the increased difficulty of repair(fine-work soldering, firmware debuging and the like) it makes way more sense to just replace the whole thing.

The author's take is detached from reality, filled with hypocrisy and gatekeeping.

This isn't nostalgia talking — it's a recognition that we’ve traded reliability and understanding for the illusion of progress.

It absolutely is nostalgia talking. Yes your TI-99 fires up immediately when plugged in, and its old. However my Commodore 64 of the same era risk being fried because the 5v regulator doesn't age well and when fails dumps higher voltage right into the RAM and CPU. Oh, and c64 machines were never built with overvoltage protection because of cost savings. So don't confuse age with some idea of golden era reliability. RAM ICs were also regularly failed in those age of computers. This is why you had RAM testing programs and socketed ICs. When was the last time, Mr author, you had to replace a failed DIMM in your modern computer?

Today’s innovation cycle has become a kind of collective amnesia, where every few years we rediscover fundamental concepts, slap a new acronym on them, and pretend we’ve revolutionized computing. Edge computing? That’s just distributed processing with better marketing. Microservices? Welcome to the return of modular programming, now with 300% more YAML configuration files. Serverless? Congratulations, you’ve rediscovered time-sharing, except now you pay by the millisecond.

By that logic, even the TI-99 he's loving on is just a fancier ENIAC or UNIVAC. All technology is built upon the era before it. If there was no technological or production cost improvement, we'd just use the old version. Yes, there is a regular shift in computing philosophy, but this is driving by new technologies and usually computing performance descending to be accessibly at commodity pricing. The Raspberry Pi wasn't a revolutionary fast computer, but it changed the world because it was enough computing power and it was dirt cheap.

There’s something deeply humbling about opening a 40-year-old piece of electronics and finding components you can actually identify. Resistors, capacitors, integrated circuits with part numbers you can look up. Compare that to today’s black-box system-on-chip designs, where a single failure means the entire device becomes e-waste.

I agree, there is something appealing about it to you and me, but most people don't care....and thats okay! To them its a tool to get something done. They are not in love with the tool, nor do they need to be. There were absolutely users of TI-99 and C64 computers in the 80s that didn't give two shits about the shift register ICs or the UART that made the modem work, but they loved that they could get invoices from their loading dock sent electronically instead of a piece of paper carried (and lost!) through multiple hands.

Mr. author, no one is stopping you from using your TI-99 today, but in fact you didn't use it to write your article either. Why is that? Because the TI-99 is a tiny fraction of the function and complexity of a modern computer. Creating something close to a modern computer from discrete components with "part numbers you can look up" would be massively expensive, incredibly slow, and comparatively consume massive amounts of electricity vs today's modern computers.

This isn't their fault — it's a systemic problem. Our education and industry reward breadth over depth, familiarity over fluency. We’ve optimized for shipping features quickly rather than understanding systems thoroughly. The result is a kind of technical learned helplessness, where practitioners become dependent on abstractions they can’t peer beneath.

Ugh, this is frustrating. Do you think a surgeon understands how a CCD electronic camera works that is attached to their laparoscope? Is the surgeon un-educated that they aren't fluent in circuit theory that allows the camera to display the guts of the patient they're operating on? No, of course not. We want that surgeon to keep studying new surgical technics, not trying to use Ohm's Law to calculate the current draw of the device he's using. Mr author, you and I hobby at electronics (and vintage computing) but just because its an interest of ours, doesn't mean it has to be of everyone.

What We Need Now: We need editors who know what a Bode plot is. We need technical writing that assumes intelligence rather than ignorance. We need educational systems that teach principles alongside tools, theory alongside practice.

Such gatekeeping! So unless you know the actual engineering principles behind a device you're using, you shouldn't be allowed to use it?

Most importantly, we need to stop mistaking novelty for innovation and complexity for progress.

Innovation isn't just creating new features or functionality. In fact, most I'd argue is taking existing features or functions and delivering them for substantially less cost/effort.

As I'm reading this article, I am thinking about a farmer watching Mr. author eat a sandwich made with bread. Does the Mr author know when to till soil or plant seed? How about the amount of irrigation Durum wheat needs during the hot season? How about when to harvest? What moisture level should the resulting harvest have before being taking to market or put in long term storage? Yet there he sits, eating the sandwich blissfully unaware of all the steps and effort needed to just make the wheat that goes into the bread. The farmer sits and wonders if Mr author's next article will be deriding the public on just eating bread and how we've forgotten how to grow wheat. Will Mr Author say we need fewer people ordering sandwiches and more people consulting US GIS maps for rainfall statistics and studying nitrogen fixing techniques for soil health? No, probably not.

The best engineering solutions are often elegantly simple. They work reliably, fail predictably, and can be understood by the people who use them.

Perhaps, but these simple solutions also can frequently only offer simple functionality. Additionally, "the best engineering solutions" are often some of the most expensive. You don't always need the best, and if best is the only option, then that may mean going without, which is worst than a mediocre solution and what we frequently had in the past.

They don't require constant updates or cloud connectivity or subscription services. They just work, year after year, doing exactly what they were designed to do.

The reason your TI-99 and my c64 don't require constant updates is because they were born before the concept of cybersecurity existed. If you're going to have internet connected devices they its a near requirement to receive updates for security.

If you don't want internet connected devices, you can get those too, but they may be extremely expensive, so pony up the cash and put your money where your mouth is.

That TI-99/4A still boots because it was designed by people who understood every component, every circuit, every line of code.

It is a machine of extremely limited functionality with a comparably simple design and construction. Don't think even a DEC PDP 11 mainframe sold in the same era was entirely known by a handful of people, and even that is a tiny fraction of functionality of today's cheap commodity PCs.

It works because it was built to work, not to generate quarterly revenue or collect user data or enable some elaborate software-as-a-service business model.

Take off the rose colored glasses. It was made as a consumer electronics product with the least cost they thought they could get away with and have it still sell. Sales of it absolutely served quarterly revenue numbers even back in the 1980s.

We used to build things that lasted.

We don't need most of these consumer electronics to last. Proof positive is the computer Mr. author is writing his article on is unlikely to be an Intel based 486 running at 33Mhz from the mid 90s (or a 68030 Mac). If it still works, why isn't he using one? Could it be he wants the new features and functionality like the rest of us? Over-engineering is a thing, and it sounds like what the author is preaching.

Apologies if my post turned into a rant.

The author's take is detached from reality, filled with hypocrisy and gatekeeping.

This isn't nostalgia talking — it's a recognition that we’ve traded reliability and understanding for the illusion of progress.

It absolutely is nostalgia talking. Yes your TI-99 fires up immediately when plugged in, and its old. However my Commodore 64 of the same era risk being fried because the 5v regulator doesn't age well and when fails dumps higher voltage right into the RAM and CPU. Oh, and c64 machines were never built with overvoltage protection because of cost savings. So don't confuse age with some idea of golden era reliability. RAM ICs were also regularly failed in those age of computers. This is why you had RAM testing programs and socketed ICs. When was the last time, Mr author, you had to replace a failed DIMM in your modern computer?

Today’s innovation cycle has become a kind of collective amnesia, where every few years we rediscover fundamental concepts, slap a new acronym on them, and pretend we’ve revolutionized computing. Edge computing? That’s just distributed processing with better marketing. Microservices? Welcome to the return of modular programming, now with 300% more YAML configuration files. Serverless? Congratulations, you’ve rediscovered time-sharing, except now you pay by the millisecond.

By that logic, even the TI-99 he's loving on is just a fancier ENIAC or UNIVAC. All technology is built upon the era before it. If there was no technological or production cost improvement, we'd just use the old version. Yes, there is a regular shift in computing philosophy, but this is driving by new technologies and usually computing performance descending to be accessibly at commodity pricing. The Raspberry Pi wasn't a revolutionary fast computer, but it changed the world because it was enough computing power and it was dirt cheap.

There’s something deeply humbling about opening a 40-year-old piece of electronics and finding components you can actually identify. Resistors, capacitors, integrated circuits with part numbers you can look up. Compare that to today’s black-box system-on-chip designs, where a single failure means the entire device becomes e-waste.

I agree, there is something appealing about it to you and me, but most people don't care....and thats okay! To them its a tool to get something done. They are not in love with the tool, nor do they need to be. There were absolutely users of TI-99 and C64 computers in the 80s that didn't give two shits about the shift register ICs or the UART that made the modem work, but they loved that they could get invoices from their loading dock sent electronically instead of a piece of paper carried (and lost!) through multiple hands.

Mr. author, no one is stopping you from using your TI-99 today, but in fact you didn't use it to write your article either. Why is that? Because the TI-99 is a tiny fraction of the function and complexity of a modern computer. Creating something close to a modern computer from discrete components with "part numbers you can look up" would be massively expensive, incredibly slow, and comparatively consume massive amounts of electricity vs today's modern computers.

This isn't their fault — it's a systemic problem. Our education and industry reward breadth over depth, familiarity over fluency. We’ve optimized for shipping features quickly rather than understanding systems thoroughly. The result is a kind of technical learned helplessness, where practitioners become dependent on abstractions they can’t peer beneath.

Ugh, this is frustrating. Do you think a surgeon understands how a CCD electronic camera works that is attached to their laparoscope? Is the surgeon un-educated that they aren't fluent in circuit theory that allows the camera to display the guts of the patient they're operating on? No, of course not. We want that surgeon to keep studying new surgical technics, not trying to use Ohm's Law to calculate the current draw of the device he's using. Mr author, you and I hobby at electronics (and vintage computing) but just because its an interest of ours, doesn't mean it has to be of everyone.

What We Need Now: We need editors who know what a Bode plot is. We need technical writing that assumes intelligence rather than ignorance. We need educational systems that teach principles alongside tools, theory alongside practice.

Such gatekeeping! So unless you know the actual engineering principles behind a device you're using, you shouldn't be allowed to use it?

Most importantly, we need to stop mistaking novelty for innovation and complexity for progress.

Innovation isn't just creating new features or functionality. In fact, most I'd argue is taking existing features or functions and delivering them for substantially less cost/effort.

As I'm reading this article, I am thinking about a farmer watching Mr. author eat a sandwich made with bread. Does the Mr author know when to till soil or plant seed? How about the amount of irrigation Durum wheat needs during the hot season? How about when to harvest? What moisture level should the resulting harvest have before being taking to market or put in long term storage? Yet there he sits, eating the sandwich blissfully unaware of all the steps and effort needed to just make the wheat that goes into the bread. The farmer sits and wonders if Mr author's next article will be deriding the public on just eating bread and how we've forgotten how to grow wheat. Will Mr Author say we need fewer people ordering sandwiches and more people consulting US GIS maps for rainfall statistics and studying nitrogen fixing techniques for soil health? No, probably not.

The best engineering solutions are often elegantly simple. They work reliably, fail predictably, and can be understood by the people who use them.

Perhaps, but these simple solutions also can frequently only offer simple functionality. Additionally, "the best engineering solutions" are often some of the most expensive. You don't always need the best, and if best is the only option, then that may mean going without, which is worst than a mediocre solution and what we frequently had in the past.

They don't require constant updates or cloud connectivity or subscription services. They just work, year after year, doing exactly what they were designed to do.

The reason your TI-99 and my c64 don't require constant updates is because they were born before the concept of cybersecurity existed. If you're going to have internet connected devices they its a near requirement to receive updates for security.

If you don't want internet connected devices, you can get those too, but they may be extremely expensive, so pony up the cash and put your money where your mouth is.

That TI-99/4A still boots because it was designed by people who understood every component, every circuit, every line of code.

It is a machine of extremely limited functionality with a comparably simple design and construction. Don't think even a DEC PDP 11 mainframe sold in the same era was entirely known by a handful of people, and even that is a tiny fraction of functionality of today's cheap commodity PCs.

It works because it was built to work, not to generate quarterly revenue or collect user data or enable some elaborate software-as-a-service business model.

Take off the rose colored glasses. It was made as a consumer electronics product with the least cost they thought they could get away with and have it still sell. Sales of it absolutely served quarterly revenue numbers even back in the 1980s.

We used to build things that lasted.

We don't need most of these consumer electronics to last. Proof positive is the computer Mr. author is writing his article on is unlikely to be an Intel based 486 running at 33Mhz from the mid 90s (or a 68030 Mac). If it still works, why isn't he using one? Could it be he wants the new features and functionality like the rest of us? Over-engineering is a thing, and it sounds like what the author is preaching.

Apologies if my post turned into a rant.

The author's take is detached from reality, filled with hypocrisy and gatekeeping.

This isn't nostalgia talking — it's a recognition that we’ve traded reliability and understanding for the illusion of progress.

It absolutely is nostalgia talking. Yes your TI-99 fires up immediately when plugged in, and its old. However my Commodore 64 of the same era risk being fried because the 5v regulator doesn't age well and when fails dumps higher voltage right into the RAM and CPU. Oh, and c64 machines were never built with overvoltage protection because of cost savings. So don't confuse age with some idea of golden era reliability. RAM ICs were also regularly failed in those age of computers. This is why you had RAM testing programs and socketed ICs. When was the last time, Mr author, you had to replace a failed DIMM in your modern computer?

Today’s innovation cycle has become a kind of collective amnesia, where every few years we rediscover fundamental concepts, slap a new acronym on them, and pretend we’ve revolutionized computing. Edge computing? That’s just distributed processing with better marketing. Microservices? Welcome to the return of modular programming, now with 300% more YAML configuration files. Serverless? Congratulations, you’ve rediscovered time-sharing, except now you pay by the millisecond.

By that logic, even the TI-99 he's loving on is just a fancier ENIAC or UNIVAC. All technology is built upon the era before it. If there was no technological or production cost improvement, we'd just use the old version. Yes, there is a regular shift in computing philosophy, but this is driving by new technologies and usually computing performance descending to be accessibly at commodity pricing. The Raspberry Pi wasn't a revolutionary fast computer, but it changed the world because it was enough computing power and it was dirt cheap.

There’s something deeply humbling about opening a 40-year-old piece of electronics and finding components you can actually identify. Resistors, capacitors, integrated circuits with part numbers you can look up. Compare that to today’s black-box system-on-chip designs, where a single failure means the entire device becomes e-waste.

I agree, there is something appealing about it to you and me, but most people don't care....and thats okay! To them its a tool to get something done. They are not in love with the tool, nor do they need to be. There were absolutely users of TI-99 and C64 computers in the 80s that didn't give two shits about the shift register ICs or the UART that made the modem work, but they loved that they could get invoices from their loading dock sent electronically instead of a piece of paper carried (and lost!) through multiple hands.

Mr. author, no one is stopping you from using your TI-99 today, but in fact you didn't use it to write your article either. Why is that? Because the TI-99 is a tiny fraction of the function and complexity of a modern computer. Creating something close to a modern computer from discrete components with "part numbers you can look up" would be massively expensive, incredibly slow, and comparatively consume massive amounts of electricity vs today's modern computers.

This isn't their fault — it's a systemic problem. Our education and industry reward breadth over depth, familiarity over fluency. We’ve optimized for shipping features quickly rather than understanding systems thoroughly. The result is a kind of technical learned helplessness, where practitioners become dependent on abstractions they can’t peer beneath.

Ugh, this is frustrating. Do you think a surgeon understands how a CCD electronic camera works that is attached to their laparoscope? Is the surgeon un-educated that they aren't fluent in circuit theory that allows the camera to display the guts of the patient they're operating on? No, of course not. We want that surgeon to keep studying new surgical technics, not trying to use Ohm's Law to calculate the current draw of the device he's using. Mr author, you and I hobby at electronics (and vintage computing) but just because its an interest of ours, doesn't mean it has to be of everyone.

What We Need Now: We need editors who know what a Bode plot is. We need technical writing that assumes intelligence rather than ignorance. We need educational systems that teach principles alongside tools, theory alongside practice.

Such gatekeeping! So unless you know the actual engineering principles behind a device you're using, you shouldn't be allowed to use it?

Most importantly, we need to stop mistaking novelty for innovation and complexity for progress.

Innovation isn't just creating new features or functionality. In fact, most I'd argue is taking existing features or functions and delivering them for substantially less cost/effort.

As I'm reading this article, I am thinking about a farmer watching Mr. author eat a sandwich made with bread. Does the Mr author know when to till soil or plant seed? How about the amount of irrigation Durum wheat needs during the hot season? How about when to harvest? What moisture level should the resulting harvest have before being taking to market or put in long term storage? Yet there he sits, eating the sandwich blissfully unaware of all the steps and effort needed to just make the wheat that goes into the bread. The farmer sits and wonders if Mr author's next article will be deriding the public on just eating bread and how we've forgotten how to grow wheat. Will Mr Author say we need fewer people ordering sandwiches and more people consulting US GIS maps for rainfall statistics and studying nitrogen fixing techniques for soil health? No, probably not.

The best engineering solutions are often elegantly simple. They work reliably, fail predictably, and can be understood by the people who use them.

Perhaps, but these simple solutions also can frequently only offer simple functionality. Additionally, "the best engineering solutions" are often some of the most expensive. You don't always need the best, and if best is the only option, then that may mean going without, which is worst than a mediocre solution and what we frequently had in the past.

They don't require constant updates or cloud connectivity or subscription services. They just work, year after year, doing exactly what they were designed to do.

The reason your TI-99 and my c64 don't require constant updates is because they were born before the concept of cybersecurity existed. If you're going to have internet connected devices they its a near requirement to receive updates for security.

If you don't want internet connected devices, you can get those too, but they may be extremely expensive, so pony up the cash and put your money where your mouth is.

That TI-99/4A still boots because it was designed by people who understood every component, every circuit, every line of code.

It is a machine of extremely limited functionality with a comparably simple design and construction. Don't think even a DEC PDP 11 mainframe sold in the same era was entirely known by a handful of people, and even that is a tiny fraction of functionality of today's cheap commodity PCs.

It works because it was built to work, not to generate quarterly revenue or collect user data or enable some elaborate software-as-a-service business model.

Take off the rose colored glasses. It was made as a consumer electronics product with the least cost they thought they could get away with and have it still sell. Sales of it absolutely served quarterly revenue numbers even back in the 1980s.

We used to build things that lasted.

We don't need most of these consumer electronics to last. Proof positive is the computer Mr. author is writing his article on is unlikely to be an Intel based 486 running at 33Mhz from the mid 90s (or a 68030 Mac). If it still works, why isn't he using one? Could it be he wants the new features and functionality like the rest of us? Over-engineering is a thing, and it sounds like what the author is preaching.

Apologies if my post turned into a rant.