The Islander

My design of the Islander came after one year of intense experimentation. Formally, the last stage had 3 more variable capacitors...but I took them out and adjusted their respective coils to a preset form...thereby eliminating of having to adjust 5 variable capacitors. My PCB design is a 'no hole' component mount. The PCB does look rather worn...that is because much experimentation (changeouts/omissions/add-ons) was done to achieve a more functional unit. All the area around the circuitry has a ground plane (front and back). The copper layout is on the 'same' side as the components. Just click on the above picture for a larger view.

In viewing the unit, please note the way the PCB is made... this is extremely important! But this will be mentioned further down the webpage. Also notice the upper coax...that went to my dipole antenna. The lower coax...which was about 9 inches in length, went to my electret mic. Since the tank circuit was NOT shielded, putting my head too close to the electret mic (mic was previously soldered directly on the PCB), I would offset the 'preset' frequency. So the nine inches of coax made a very stable unit when talking into the microphone. The two upper wires on the right were my 'hot' side and the lower right wire (in red) was my ground. Arrangement of circuitry in the VHF arena is indeed important. My sole reason for showing you this picture is again, to give you an idea of what the 'no hole' design looks like. Also, do make sure, when using your 12+ volt power supply...that you keep it as close to the circuitry as possible.

D2* - This rectifier is a 1N5401, which cross-references to an NTE5401. I have also used a 1N4001/2/3/4/5 and it has seemed to work just as well.

Mouser Electronics in the USA carries all of the transistors shown above. The picture below shows the pricing on the NTE342 and toll-free phone number for ordering the components you may need. . To find their website homepage, just go to the Yahoo Homepage and type in the keywords...Mouser Electronics.

Below are the construction plans for the PCB layout. The routing of the PCB in the template below, is exactly as the one you see in the above digital picture. I strongly suggest you go with this routing, as it has worked fine for me. Should you sway from this routing design, I would have no way to help you in finding out what the problem should be, if the unit does not function. In the VHF band arena, any detour from the said instructions could possibly warrant a 'no-go' in the end! Be very explicit and detailed when it comes to making this routing design.

Notice the orange areas and notice the white areas. The orange areas is where you will want to 'keep' the copper on the PCB. The white areas is where you want to 'take away' the copper on the PCB. This is called a 'hot island' method of making a PCB. There are no holes to be drilled, except for the NTE342 and for mounting and ground plane purposes.

First thing to do is to print out this template in black & white. Then measure the width and length for an exact measurement of 78mm X 107mm. This is crucial. If the printout of the template does not come out to these exact measurements, send the drawing to a graphics program and sqeeze and/or stretch the drawing until proper measurements are made. Once that is done, you can now make your PCB to the exact size of the drawing. Once this is done, you may proceed to make the PCB. After you have finished making the PCB, refer to the next section of how the NTE342 is positioned onto the PCB...together with the 4 mounting holes and the one continuity hole.

The above drawing is what your PCB should look like prior to soldering all of the components on the PCB. Notice the four mounting holes that are required. They are on each corner of the PCB above. Drill these 4 holes now. Next will be the positioning of the NTE342 Power Transistor. Hole #1 is for the securement of the transistor itself. The transistor will actually be on the 'backside' of the PCB. The copper, on the backside of the PCB, serves as a large heatsink for the transistor. When you purchase your transistor, there will be a hole in the top portion of the metal tab. This is where you will place a machine screw and nut. Hole #2 is where the COLLECTOR leg of the transistor will go and Hole #3 is where the BASE leg of the transistor will go. Since the transistor will be positioned on the backside of the PCB, run your two legs through the hole from the backside...coming out to the frontside. Once they are in place, both needs to be soldered (on the frontside of the PCB) on each of their respective 'hot islands'. Now let's look at the backside of the PCB...

This is where the transistor will be located...on the backside of the PCB. The left leg is the BASE leg. The right leg is the COLLECTOR leg and the middle leg is the EMITTER leg. The EMITTER leg is soldered directly to the backside of the PCB, which is the GROUND. The small white area is the area where there is 'no copper'. This is needed to keep the two outside legs from touching GROUND. Before tightening up the transistor with the machine screw and nut, be sure to use that white creamy agent between the PCB and the metal tap before tightening up the screw...this white cream is used to aid in the transfer of heat from the metal tab of the transistor to the copper on the back side of the PCB.

[You should print this drawing out (in black and white) to have a copy on hand while soldering components]

1. Electret Microphone	17. 100pF Ceramic Disk Capacitor	33. 5-30pF Variable Capacitor
2. 1uF/50v Electrolytic Capacitor	18. VK200 Choke	34. 1N914 Diode (Observe Polarity)
3. 4.7K Carbon 1/2 Watt Resistor	19. Coil	35. 1uF/50v Electrolytic Capacitor
4. 47K Carbon 1/2 Watt Resistor	20. 56pF Ceramic Disk Capacitor	36. #36 is omitted on drawing.
5. 5.6K Carbon 1/2 Watt Resistor	21. #21 is omitted on drawing.	37. 2N2907 or MPS2907 (PNP) Transistor
6. Antenna Input (50 Ohms Impedance)	22. 39pF Ceramic Disk Capacitor	38. .001 Ceramaic Disk Capacitor
7. .001uF Ceramic Disk Capacitor	23. 22pF Ceramic Disk Capacitor	39. 4.7K Carbon 1/2 Watt Resistor
8. 100 Ohm Carbon 1/2 Watt Rersistor	24.22pF Ceramic Disk Capacitor	40. 1uF/50v Electrolytic Capacitor
9. 1.2K Carbon 1/2 Watt Resistor	25. 120pF Ceramic Disk Capacitor	41. 2N3904 or MPS3904 (NPN) Transistor
10. 24pF Ceramic Disk Capacitor	26. 5-30 Variable Capacitor	42. 22K Ohm Carbon 1/2 Watt Resistor
11. 24pF Ceramic Disk Capacitor	27. Coil	43. 270 Ohm Carbon 1/2 Watt Resistor
12. Coil	28. .001 Ceramic Disk Capacitor	44. 5.6K Ohm Carbon 1/2 Watt Resistor
13. .1uF Ceramic Disk Capacitor	29. 22 Ohm Carbon 1/2 Watt Resistor	45. Coil
14. 470uF/50v Electrolytic Capacitor	30. 2N2222A or MPS2222A (NPN) Transistor	46. Refer to 'Component Placement' drawing
15. NTE5801 Rectifier (also see text)	31. Coil
16. NTE342 or 2SC1971 (NPN) Power Transistor (See Text)	32. 5.6pF Ceramic Disk Capacitor

Above is the schematic for the 7-Watt FM Transmitter. It was originally a 200mW unit, without the universal power stage added. Together with the power amp (NTE342), it then became a 7-watt unit. I used this transmitter with a open half-wave dipole antenna in a vertical position 50 feet above ground. Together with about 70 feet of coax, this transmitter delivered great audio at a distance of 10 miles...overall distance was 17 miles, but the audio signal was weak.. I had no equipment, other than a watt meter (to measure it's power) and a digital FM tuner (with a 5-LED Signal Strength Bargraph display) to use as capturing the main oscillating frequency, which was right at 87.5 MHz. This circuit worked well for me, as I had experimented with it for nearly a year. Of course, one would be better off with more equipment than I have had...to capture the main oscillating frequency. That was, by far, one of the hardest things to capture. It was thru trial and error, with the FM tuner, in finally finding out how to grab the right frequency. When I finally did get used to finding out where my 'main' frequency was, the unit performed extremely well. Like I had said above, right at 10 miles, the unit was at it's best...giving clear audible audio into the speakers of my car. With the transmitting antenna at 50 feet above ground, I decided to see how well I could receive the transmitter signal from an overpass than is exactly 15 miles from the transmitter. When I got to the top of the overpass in my car , the audio signal came in as 'clear as a bell'. I now undersand what is meant when one says FM signal travels best in a line of sight. Well, being on that overpass, if I had a strong telescope with me, I am sure I could see the 50 foot antenna in my oak tree. So with the overpass being right around 50 feet in height also, the transmitter surpassed my judgement call on its' signal. I surrender this circuit to anyone who likes to experiment in things like this...

The best possible help I could give one in making this FM unit function well, is to have a homemade watt meter and a homemade Field Strength Meter available. Together with a DVM, these two homemade devices can aid you in fine-tuning the unit and also giving you an rough idea of how much wattage you are putting out. If you can get hold of an FM tuner, with a bar-graph LED Signal Strength readout, this can aid in finding the 'main' transmitting frequency...

The three test devices above is what I had used in the complete makings of the transmitter. I had nothing else. A lot of 'trials & errors' came into play when I had to limit myself in tuning the transmitter/adjustment of coils/catching the main osciallating frequency...with just three pieces of test equipment mentioned above But it did work out well in the end. I do believe...

If there is any questions or concerns regarding this project, do not hesitate to send me a letter. I am here to help in any way that I can...

This webpage has just been updated...to make it even easier to understand the complete makings of the unit. Should you happen to spot something that looks 'not quite right' or something that I might have not explained in more detail...do drop me a line and I will get back with you on it.