M620- Software Revision Plan

Firmware Version 1  DDS W/8x2 LCD, S-BARGRAPH, VOLTS
 OLD-> NEW
1     20G  -> 1A  EXISTING VERSION-G: DDS60 w/30 MHZ Clock, 20M
2 H  -> 1B  Vin Volt Scale (Vin/4)
3 I ->  1C  DDS w/66.666MHZ Clock, 20M (14.3MHZ)
4 J  -> 1D  CAL MENU
5 K ->  1E  BANDS 20, 17, 15, 12, and 10 (Select @ compile)
6 L  -> 1F  FREQ DISP RE-FORMAT
DO NOT USE: 1G
7 M ->  1H  RX / TX RE-SCALE w/ PTT + BARGRAPH REFORMAT
8 N  -> 1I  MEMORIES
O = NOT USED
9 P  -> 1J  SETUP MENU
10 Q  -> 1K  TBD - 12/10 MTRS?
11 R  -> 1L  TBD - 6MTRS? 
12 S  -> 1M  TBD - SCANNING?
13 T  -> 1N  TBD - LAST FREQ MEMO?
DO NOT USE: 1O
14 U  -> 1P  TBD - DUAL VFO?
15 U  -> 1Q  TBD - ?
16 W  -> 1R 
17 X  -> 1S 
18 Y  -> 1T 
19 Z  -> 1U
20       1V
21       1W
22       1X
23       1Y
24       1Z

M620 - Just in Case (Proto finds a home)

M620 - X3 Board Schematic

M620 - X2 IF Board ~ Prototype

M620 - X3 Board proto ( drill guide )

This is the hole pattern for copper clad board proto

M620 - Power Amp



PART 4 – RF/PA Board Construction

 The concept is to provide enough power, hopefully a couple of Watts, to allow the transceiver to be heard someday on the bands!  The RF board is designed only to provide a few (hundred?) milliwatts of output.  The design trick here is to provide a reasonable amount of power without quickly draining all the battery power.  A 5W transmitter can easily draw several Amps of power. The PA board also has a LPF, to keep us legal as far as spurious emissions, and provide T/R switching.  The “extra” cap across the output inductor and careful tuning really helps the efficiency, as this filter matches the output of the amplifier to the antenna as well as suppressing the harmonics.  This board is a simple linear FET amp basically copied from one of the many in the literature, but in a form factor we can fit.  This is one circuit that probably demands more attention, but works fine for now.  

Build test the circuits by injecting a small RF signal and tuning the LPF and amp bias set just to have enough power out to see the RF output using a scope or the power detection circuit connected to a DVM.  Moving the LPF coil’s windings closer together one at a time tunes the filter.  This takes a little time, but this circuit can deliver over 5W when carefully adjusted. Conversely, if the inductors are off by even one turn the efficiency will be very poor.   For the final tuning I connect the LPA to the RF board and the output to a dummy load. To inject the test signal I use a stereo phone connector with a mono jack to disable the internal microphone on the RF board’s test connector (JP11) the tip is the CW signal and the ring disables the microphone output, at it ground to the sleeve when a mono jack is used. Only key the PTT switch for quick measurements being careful not to overheat the LPA’s transistors.  The CW level is adjusted from zero and increased until the power stops rising, then back off the injected signal until the output falls. Then final adjustments can be done for max power. I actually use a PC soundcard with a CW program for this signal.

M620 - DDS/Controller Board



PART 2 – VFO Controller Board Construction

The concept of the controller board is to provide a simple and stable local oscillator source controller as well as providing a user interface and some metering capability. Typically these bands use a frequency doubled VFO, which are usually touchy, or Crystal controlled which limit the frequency. A DDS probably not the most cost effective way to go, but it is certainly accurate and flexible. The design also incorporates A/D inputs that form a voltmeter to be used to sample the battery voltage as well as a signal in and power out for the display.  The first prototypes simply controlled a DDS-60 daughter card because the DDS was hard to prototype due to the fine SMT package pitch pin put of these devices.  Provisions were made to incorporate the DDS circuitry on the board as well; just not as elaborate as the DDS-60’s.

The cornerstone of this design would be the 8x2 LCD display – HDM08216H-3-S00S - which fits in the proposed case.  [C], [D] The reason I specified this exact part is because the LCD attaches directly to the controller board which is just slightly larger than the display, so the footprint needs to correctly line up. And it was also the “thinnest” one available.  The 16-pin connector actually does a pretty good job of supporting the display, but as a percaution, an insolating layer made out of an old business card was trimmed and tacked to the bottom of the LCD display with a couple dabs of glue as there are some metal tabs that come perilously close to the circuits of the controller board.   I later added a couple of screws and standoffs for a little more mechanical stability.  

The other main components that the proto design uses are a SMT PIC 16F88 [A] and the AD9851 DDS [B] plus a rather curious combination of other thru-hole and SMT parts.  The main reasoning for some parts which could only be found in SMT and some are simply what I had on had to build up several boards.

 Building the board using a technique using fine wire solder on each IC pin, followed by a solder wick to clean up any shorts between the pins worked quite well for soldering the ICs.   Once the board is built, it is programmed via the provided programming header [G]. Install the LCD directly to the controller board after some perliminary testing.

KD6VKF HF Handheld SSB QRP Radio ~ Assembly

M620 -DDS Synthesizer Prototype

M620 -X1 PC Boards