A prototype for the latest Star Ring. Q1, Q2, and Q3 use this N-channel MOSFET. The circuit runs from a 3V battery. When one of the transistors is turned on, the six red/green LEDs in the associated row can be turned on or off using six microcontroller outputs. At least that’s the theory. I built this, and it works – barely. The LEDs are extremely dim. Why?

Hint: what gate voltage is needed to turn on the transistors?

I’m not sure if there’s any way I can patch this, without having to redesign a new board.

The Atmel ICE programmer/debugger has its SWD connector pins reversed from the standard ARM Cortex debug connector. Arghh… why? It’s the same physical connector (5×2 0.05 inch polarized male), but the pins are rotated 180 degrees from the standard, as if the cable were plugged in backwards. Incredibly, it also ships with a 180-degree reversing cable, so it works – as long as you use their cable. It’s not a mistake: the product is actually designed around a reversed connector with an un-reversing cable.

WHO BUILDS A PRODUCT THIS WAY?? I shake my fist at you, Atmel hardware designer. This is like designing an electric outlet where 110V and ground are swapped from their normal locations, but bundling it with an appliance cord that unswaps them.

The problem began when I grew tired of Atmel’s tiny 4-inch cable, and decided to get a replacement cable. Naturally I used a standard 10-pin ribbon cable with 5×2 0.05 inch connectors on each end: Adafruit’s purpose-made SWD cable for ARM development. I couldn’t understand why it didn’t work, and why strange things happened when it was plugged in.

After scratching my head for a while, I noticed something odd. The title photo shows both the original cable and the Adafruit cable connected to the Atmel ICE. Notice how one has the red stripe on the right, and the other on the left? Ouch!

From looking at the original Atmel cable, it’s not at all obvious that the pins are reversed. It looks like a straight-through cable, because each connector is crimped straight on to the 10-pin ribbon, with no crossing wires. But a more careful inspection reveals that one of the connectors is crimped on so it’s facing the opposite direction of the other, resulting in a 180-degree rotation of the pin assignments. It violates the rule of the cable’s red wire indicating the location of pin 1. (Ignore the extra 6-pin header, which is used for other devices)

The good news is that there’s no permanent damage to my ARM board. The bad news is that I still need a replacement cable, but now I need to build a reversing one.

How efficient is a typical 5V AC-to-DC power supply? I’m digging through my box of assorted power supplies from past projects, looking for something appropriate for a large LED matrix, and noticed the one pictured above. 110V 0.8A input – that’s 88 watts. 5V 4A output – that’s 20 watts. Is the power supply really only 22.7% efficient, or is my reasoning flawed somehow? I would have expected a switching power supply like this one to have much better efficiency than that. A quick search for information on “level IV power supplies” suggests they must be 85%+ efficient, so something doesn’t add up.

I’m experimenting with methods to limit the inrush current when an SD card is inserted, and beginning to wonder whether my solutions are worse than nothing.

When an SD card is inserted into a board that’s already powered on, a large amount of current will flow briefly, as the card’s internal capacitors are charged through its 3.3V supply pin. This is called inrush current. If the inrush current is too large, it can overtax the main board’s voltage regulator and capacitors, causing the board’s supply voltage to drop temporarily. If the voltage drops far enough, it may cause the board’s microcontroller to do a brownout reset. That’s what happened with early versions of the Floppy Emu. It wasn’t really a problem, because you’ll almost always want to perform a reset anyway after inserting a new card, but it was slightly annoying.

In later versions of the Floppy Emu, I added a 1 uH inductor and 10 uF capacitor for the SD card, as shown in the circuit schematic above. Later the capacitor was changed to a 33 uF tantalum. The purpose of the inductor was to limit the inrush current, preventing the main board’s supply voltage from sagging and causing a brownout. And it worked, mostly, as confirmed by observing the main supply and SD card supply voltages on a scope during card insertion. The exact behavior depended on the brand and type of SD card and the card’s internal circuitry. Some types of cards still caused a brownout reset when hot-inserted, but it was rare.

Revisiting this question again recently, I noticed that the inductor created a new issue that may be worse than the one I was trying to solve. When the SD card is inserted, its 3.3V supply pin doesn’t go cleanly from disconnected to connected. Instead it bounces and wiggles over a period of microseconds to milliseconds, just like the contacts of a mechanical switch. As a result, the inrush current isn’t one single burst, but a series of short on/off current pulses. Because of the presence of the inductor in the circuit, these pulses create voltage spikes on the SD card’s 3.3V supply pin. They’re brief – lasting about 100 ns – but some of the spikes go above 4V. Despite their brevity, I’m wondering if they’re high enough to damage the SD card.

Using an inductor seems to be a pretty standard solution for SD card inrush current, but I’ve never seen any discussion of the voltage oscillation and spikes this can cause for the card’s supply. An alternative is a power management IC with “soft start” behavior, but I’m not interested in adding extra chips in this case. I’m starting to think it may be best to remove the inductor, and connect the card’s 3.3V supply directly to the board’s 3.3V supply. Better to cause a nuisance brownout due to high inrush current, than to risk damaging the card with voltage spikes – and still have brownouts sometimes anyway. Have you ever dealt with this topic? How did you address it?

I’ve been working on version 3 of Star Ring, my fun but useless circular LED blinker, and I had an idea. Do I really need current-limiting resistors for the LEDs? Or can I effectively control the LED current using PWM?

Normally a resistor is always needed in series with an LED. Without the resistor, a very high current would flow, destroying the LED. The max DC forward current is specified in the LED datasheet, and is typically something like 30 mA. Often the datasheet will also specify a peak forward current, higher than the DC max, for applications where the LED is rapidly switched on and off with PWM. But how can I calculate what the current will be, if there’s no resistor? As usual, the answer is in the datasheet.

Star Ring is an ATTINY84A microcontroller powered by a 3V CR2032 watch battery. For the sake of this analysis, we’ll assume I’m using this Lite-On dual-color LED with independent red and green elements. The datasheets for the microcontroller and the LED both include graphs of voltage vs current:

The more current that’s drawn from an ATTINY I/O pin, the more the voltage will sag below the 3V supply. And the more current that’s passed through the LED, the more the voltage across it will rise. At some point these two graphs will intersect. You have to exchange the X and Y axes of the LED graph, and extrapolate the ATTINY graph a little, but for the green LED the crossing point is about 2.0V at 25 mA. In the absence of any current-limiting resistor, that’s what you’ll get – theoretically.

25 mA is below the LED’s 30 mA max current rating, so that’s fine. It’s also below the ATTINY’s 40 mA max current per I/O pin, so that’s fine too (although it’s curious why the ATTINY IV graph only goes up to 20 mA). So for this combination of hardware, it looks like current-limiting resistors aren’t needed at all. If 25 mA is more current than is desired, PWM can be used to reduce the average current to something lower.

In reality, the DC current without a resistor will be lower than 25 mA, because of the internal resistance of the CR2032 battery, which I’ve estimated is something like 13 ohms. At 25 mA, even with a fresh 3V battery, the supply voltage to the ATTINY will only be 2.675V due to the battery internal resistance. The I/O pin output voltage will sag further below 2.675V, and those two IV curves will cross at a different point with a current lower than 25 mA. A simple experiment could find the exact number.

 
Ignoring My Own Advice

Despite this conclusion, I’m probably going to keep the current-limiting resistors, for a few reasons. The graph for the red LED is different than the green, and the no-resistor current will be higher, potentially at an unsafe level. I’m also uncertain whether 25 mA is really OK for the ATTINY – it’s below the 40 mA absolute max rating, but the rest of the datasheet implies 20 mA is the recommended maximum, and there’s no max continuous vs peak current distinction I can see for the I/O pin. I’m also concerned about what happens during debugging or a software crash when my PWM code unexpectedly stops running, and the LED is left constantly on until I can manage to do a reset or kill the power. The resistors will provide some valuable insurance, even if they’re not absolutely required.