Catching The Full Wave: Bridge Rectifier On The Oscilloscope
As my ham radio journey takes me on a more formal study of electricity, my home laboratory grows. I remember purchasing the Tektronix 2465 a few years back on a suggestion of a friend, not having a clue what I was doing with it. I just knew that real electronics enthusiasts had an oscilloscope.
Now that I am crawling my way through the Sedra/Smith’s Microelectronic Circuits tome, I have plenty of reasons to fire up my mushrooming pile of test equipment.
Let’s start with this circuit, the bridge rectifier.
The bridge rectifier is a fairly simple circuit to build, consisting of only four diodes (1N4001 in this case) and a load (10kΩ resistor). In the Multisim sketch above, the device on the left is a function generator producing a 5 volt peak-to-peak 60 Hz sine wave. On the positive half-wave of the signal cycle, the function generator’s positive terminal feeds into node D1/D2 of the four diodes forming the bridge rectifier. This positive signal forward biases D2, allowing the signal to continue on toward the load R1. D1 and D4, however, are reverse biased, and the signal is only able to conduct through D2. On the negative half-wave of the sine signal cycle, the function generator’s negative terminal now feeds a positive signal into node D3/D4. The signal now forward biases D4 and reverse biases D3 and D2. This half signal proceeds through the load R1 in the same direction as the positive half-wave portion of the signal did. All of the electricity conducting through the load in the same direction is considered direct current, as it does not have a component that flows in the reverse “backward” direction (as the original imputted sine wave did). Therefore, the bridge rectifier has done its job of “rectifying” alternating current into direct current.
By placing oscilloscope leads across the load resistor, the desired output of the bridge rectifier can be seen, at least in theory. Below is the Multisim oscilloscope simulation result. The bolded reference line is at zero volts. You will note that this “full-wave” rectifier has produced a waveform that is more or less continuously greater than zero volts. As we will see, this is in contrast to the “half-wave” rectifier, where there is no voltage seen when the originating sine wave enters its negative half.
In my home lab, I went ahead and set up a bridge rectifier on a breadboard, and set out to show its characteristics on my oscilloscope.
Part of the new fleet of test equipment are these two beauties, the Topward 8112 function generator producing a 60 Hz signal shown to be 5 volts peak-to-peak on the oscilloscope. And a Fluke 45 digital multimeter which will come in handy later.
After constructing the circuit exactly as shown in the schematic, I hooked up the oscilloscope across the resistor and found a trace that looked like a half-wave rectifier instead of a full-wave. This pretty much looks like a circuit consisting of an sinusoidal signal traversing through a single forward-biased diode. There is no inversion of the negative portion of the sine wave, as seen with the full-wave rectifier, rather the negative portion of the wave just turns in to zero volts. In essence, unlike the full-wave rectifier, only half of the original sine wave is “rectified” into direct current. This is NOT what this circuit should look like on the oscilloscope.
Based on some earlier work, I expected though that this is what the oscilloscope would show without a bit of careful consideration. It turns out that this oscilloscope trace is not the result of the circuit malfunctioning, but rather a poor testing design creating a false result.
Remember the circuit diagram. The signal generator produces a signal that enters into the bridge rectifier at two distinct nodes D1/D2 and D3/D4. The signal generator needs to be electrically isolated from the output of the bridge rectifier, which occurs through nodes D2/D4 and D1/D3. Instead, however, the oscilloscope and function generator share a single ground, the earth ground in my house when I plug the unit into the wall. This makes both node D3/D4 and D1/D3 grounded which in essence creates a short circuit across diode D3. Without D3, the circuit now functions as a half-wave rectifier.
The multimeter was used to prove that indeed the oscilloscope and function generator grounds were shared. Everything was unplugged from each device and the digital multimeter was set to resistance. Checking the resistance between the outer shields of the BNC connectors of the oscilloscope and function generator showed none, indicating a short circuit, and proving that this was the cause of the bridge rectifier’s apparent malfunction.
In order to fix this issue, I checked to see if my new TekPower TP-3003D-3 power supply shared a common ground as well. It did not! There were several megaohms of resistance between the ground terminal of the supply and the generator. So, I connected the oscilloscope probe ground and the function generator ground to one of the negative terminals of the power supply and checked the output waveform. It was still not correct.
I had one last trick up my sleeve. I declared the function generator’s ground as the common reference ground of the circuit. I attached one oscilloscope probe to one side of the load resistor (the top trace) and the other oscilloscope probe to the other side of the load resistor (the bottom trace). I attached the oscilloscope probe ground leads to the function generator ground. The results are shown in the oscilloscope trace below.
In essence, I can see that the top trace is displaying a half-wave rectifier. The bottom wave is showing another half-wave rectifier out of phase with the top trace. In fact, this bottom trace has been inverted, and this waveform now appears upside-down with the humps going upward, when really they would be going downward with negative voltages.
However, the inversion of the second signal is important, because now I can do math with the oscilloscope. Take a look at the third row of controls on the scope below. First I want to “Chop” the displayed signal as this will allow us to see the waveforms better. I have already inverted the signal. Now I want to add the first (upright) and second (inverted) channels together, essentially performing a subtraction function.
Revisit the image of the oscilloscope display above, and you can see the middle trace is now showing a full-wave rectifier. The middle waveform is the mathematical operation of Ch1 minus Ch2 as performed by the oscilloscope.
And sure enough, when you take a voltage reading with the multimeter across the load resistor, you can see a 1.8 V output of direct current. Woo hoo!
I used the new AI image feature on this WordPress site to prompt a proud scientist overlooking the display of a full wave rectifier on his oscilloscope. So darn goofy! My favorite part is the Hollywood vanity lights just like in a professional lab! It is also hard to tell exactly why he is so proud given those results…
It is not surprising that I have a interest in test equipment. Learning the nuances, limitations, and intricacies of testing is paramount, or else you can make what I would refer to in my other life as iatrogenic errors. This little experiment is perfect for showing how something that works exactly as it should can be deemed malfunctioning due to misinterpretation of a lab test. While getting it wrong with this device in my little electronics laboratory is inconsequential, bad testing in the real world can be disastrous.
So the lesson here? Always look for that common ground.
So far away,
KM1NDY