CANADUINO® 60kHz WWVB MSF JJY60 Atomic Clock Receiver - Made in Canada (USMCA Complaint = no tariffs for US customers)

Packaging was pretty robust - the board and bar antenna were packed securely in a capped, sturdy plastic tube. It just took a tap on the opened end for it to slide out. The device came with printed documentation and usable references to part data if needed. After soldering down a 5-pin breakaway header on the board, I put it down on a breadboard and wired it to an Arduino, and wrote a short test sketch to time the edges on the T pin, and saw the right kind of timings (800ms/200ms etc). This was done on a bench in the man cave/Faraday cage, so that's pretty impressive performance. As a secondary check, I turned on an LF receiver in the shack and verified the pulses lined up with what I heard on WWVB. Looking forward to writing a time decoder for this very slow and very accurate PWM'd bit stream. Remember to pull down the P1 pin to turn on the receiver. It doesn't draw a lot of current (about 50 uA) when it's running, and draws near nothing (0.1uA) when you power it down (by pulling P1 up). The included documentation describes cycling this pin to retrigger the AGC logic to hasten signal acquisition time. You might therefore want to dedicate an Arduino output pin to controlling P1 rather than just grounding it. For my first test, I just grounded P1 and signal was acquired within seconds of power up. Standard shipping is via the Canadian and US Postal system; it took about a week and a half to get here. Seller was really quick to reply on a shipping question. He didn't solicit a review from me, I'm just impressed with this inexpensive, sensitive receiver giving me WWVB on a pin.

This is a receiver for the WWVB US time signal at 60 kHz. A tiny crystal is provided for the desired signal, depending on your country. This crystal must be very carefully soldered to the circuit board, quickly to avoid damage. The antenna and header pins also require soldering. As noted elsewhere, the PDN pin MUST be grounded to enable the receiver. After soldering, the device was powered up and instantly began recovering the time signal. The ferrite rod antenna is much larger and more sensitive than the similar tiny antennas found in most "Atomic Clocks" - my testing took place at 1500 hrs. in the northeast USA (full daylight)! I highly recommend this device for timeheads.

Solder pads for crystal are under-engineered. It comes with crystal detached and you have to solder it on. Gave each pad a little heat, attached crystal, all seemed fine. Started up the receiver, red light wouldn't shut off even after half an hour. Checked the crystal again, the crystal was falling off with both pads still attached to it. Spent a half hour trying to get solder to take on the empty area were the pads were with no luck. Didn't even see any conductive material to solder. I've been building kits for decades and rarely came across crap like this except for dubiously-cheap Chinese stuff. Waste of time and money.

Just picked up from mailbox. Read the three page pdf from their website. Three minutes of soldering. works well. I added a speaker so I can hear the beeps. At 5 volts, uses 7ma approx.

The 100 mm ferrite-rod antenna performs well. I'm nearly 1000 miles NW of WWVB in Ft. Collins CO and this module picks up the signal (with only occasional glitches) around the clock, 24/7 and not just special times at night or dawn/dusk. You should orient the antenna (approximately, nothing precise needed), and keep some distance from metal surfaces and noisy electronics like a cell phone or switching power supplies (eg. any modern wall-wart power supply). Don't know how well the scope photo shows it, but I see about 5 msec RMS timing jitter on the rising edge of the output signal relative to an ovenized 1-PPS reference, in this case around sunset. During the day it's around 10 ms RMS. Obviously this is a long way from single-shot GPS timing but it's pretty small, cheap, doesn't need a sky view, no warmup, and it only draws 43 uA at 3 V running at full power.

I bought it to replace an atomic clock radio module in a digital clock. It does not work. I find the instructions very lacking - their web site directs you to "open source" design files, where you have to make an account. It might be nice for some experimenters that know what they are doing, but if you just want to fix your clock that doesn't sync to WWVB - this isn't it.

I've had other WWVB modules before, this one is easily the best. The antenna module is very well built with nice thick wires. It seems like this module also picks up the WWVB signal cleaner than the other 2 modules I tried in the past. Professional packaging and it arrived (to the USA) faster than predicted.

EXCELLENT!! This is a kit. You will need some soldering skill and a little more than beginners electronics skill. Do go to the Canaduino website for information on using it. I have uploaded images of the minimum hookup that gets it running. If you connect it as shown (PDN connection grounded) the PDN LED will be off and then a minute or two after you have it connected to power ( 3 to 15 VDC) the OUT LED should begin blinking irregularly (data is coming out). This is a very nice kit and compatible with most Arduinos (the out signal is 3.3 VDC which is fine for 3.3 or 5 V Arduinos). Good Luck!

I designed a decoding board to be driven by a 60KHz r.f. signal from the Rugby transmitter (which is no longer at Rugby, by the way). When this minute receiver arrived, I found that half the circuitry on my pcb was already inside the encapsulated receiver. It is a Phase Lock Loop (PLL). The advantages of a PLL is that it can cut through noise and deliver a clean output, albeit logic or simply ON/OFF. Their response to a synchronised signal is extremely fast and the rise and fall times are so brief as to be almost immeasurable i.e. nanoseconds. However, they do take a finite time to synchronise, sometimes minutes, but usually <30 secs or so, dependent upon signal strength. This receiver, supplied by Universal Solder, has a sensitivity of 4 uV, which is quite respectable for a ferrite aerial. For those of you who reside at extreme distances from a transmitter, and who find reception poor to impossible, the signal to noise ratio may be improved by adding ferrite rods in a bundle (3 or so), surrounding the one already connected to this receiver. There have been some excellent reports about this receiver when operated at vast distances from their respective transmitters, especially from large countries like Canada and the U.S. The receiver runs at a maximum of 5 volts and burns micro-watts of energy, it being CMOS based. The output pulses are DC, not r.f., and their amplitude will be within a few percent of the supply rail voltage. The minimum operating supply is 3.5V. at which it will perform quite well. The aerial's ferrite-mounted coil is solid copper wire, not Litz wire, and is therefore quite brittle by comparison. Whilst it will tolerate a reasonable amount of flexing, great care needs to be taken when handling the 'heavy' ferrite rod and the minuscule micro-miniature p.c.b. when soldering etc. Namely, don't allow the ferrite aerial to dangle on the aerial wire, even accidentally. A second pair of hands will be useful when soldering the tiny lands associated with the additional connections. Whilst we are always keen to 'give it a burn', you are strongly advised to mount the pcb and aerial as soon as you have made all the connections. You should browse for UniversalSolder.ca and select the device from the list of other units supplied by this company. The instructions are clear and easy to follow ... just three pages. A point to note. Holding the receiver in your fingers will very likely introduce spurious or weakened r.f. signal response, as will the proximity of other loose wiring e.g. on a test rig. Leave the unit alone and be patient. Give it at least a minute to stabilise and produce pulses ... an oscilloscope isn't a must, but will prove quite reassuring. For MSF Rugby users in the UK, the first 0-100mS is the Seconds' Pulse. From 100-200 is the code (one bit per second) and from 300-400mSecs is the 'B' code. A fully detailed information sheet may be found on Wikipedia MSF Rugby, if, like me, you are designing your own decoder using hardware. All the work is done for you in this receiver, it producing nothing but seconds and coded output. In terms of performance, I don't think it will ever be bettered, as physics, in this case, have been mastered. It is a well- designed circuit, its small size enhancing performance. P.S. You may find it difficult to remove the ferrite rod and circuit board from the 'test tube', as they are rammed in to prevent movement during transit, and pulling the board to extract the ferrite via its aerial wiring is not recommended! Saw off the end of the tube and push the ferrite rod out with a pencil ... better safe than sorry. Apex Systems (UK) Ltd

Pessimo

This is not a true kit as with few solder points was too simple. Connecting it and testing was a little more challenging. I would give it 2/5 difficulty as one has to wait for synchro. The info on the manufacturer web site, especially the stm32 clock is very good even only for this module alone and not considering the whole project described there. Much more sensitive than the desk marathon clock I have that never synchronizes. One needs other components if a full atomic radio clock is the end goal.

About 40 years ago I built a clock from the design in Radio & Electronics World (April 1983) and it has proved very reliable. In that time I have only had to replace the Z80 processor, which may have failed from overheating. But I never had much success with the 60kHz receivers (two designs) and aerials (ferrite rod and wire frame aerials). Aerials extremely directional and poor reception in daylight hours. This Canaduino module has transformed the clock. It comes as a kit, but very little soldering required. But you do need to be competent in soldering tiny parts (the crystal). It was very well packed inside a small plastic box. I don't know whether the box was intended to house the built-up unit, but that's what I did. With careful measurements and drilling I mounted the ferrire rod with cable ties, the PCB with M2.5 screws, and two phono sockets. One for power, the other for data. It seems quite tolerant of direction, but I'm relatively close to the Anthorn transmitter (about 135 km, 84 miles). It may be more critical at greater distances. Highly recommended.

Odd that the AGC contact is not same size nor inline with other pin holes, so can't have it on same header. Crystal not off-frequency by a few Hz, as datasheet recommends. Otherwise a great product, that I'm glad someone has made available.