SYNTHESIS SYSTEMS JLH 831 Assembly instructions The JLH-831 interval selector voltage switch has options to consider before beginning construction. These options must be determined as component selection and placement will be impacted. The first option is selecting the intervals for your voltage switch. Resistor values in the intervals selector divider chain determine what intervals will be produced in each of the five up and five down shift positions. The PCB is marked with resistor values that will produce the shifts I originally selected for the 831 prototype. I found these musically useful and you may also. If you prefer other interval options, please refer to the document "Selecting alternate intervals for your 831 voltage switch." The second option concerns the 1-volt-per-octave DC accuracy of the 831. There are two methods to achieve this accuracy. You must select one or the other prior to construction as component placement varies Method # 1 involves carefully hand matching some critical resistors in the circuit. If you use this method, there is no need to install the 1-volt-octave trimmers. I believe this method is the best alternative for building the 831. However, be aware that VERY close matching is essential. I recommend that the 10K resistors be matched within 0.3 ohms and the 100K resistors be matched within 3 ohms. You need at least a 5 1/2 digit digital meter to accomplish that level of matching accuracy. Method # 2 Allows a 1-volt-per-octave trimmer to be installed in series with the input resistor so that the gain of the 1-volt-per-octave DC control voltage can be controlled in the first op-amp stage. This single trimmer can offset any error in the entire 831 circuit path for the 1-volt per-octave control voltage. While this method might seem the best option, trimmers are not as stable as fixed resistors. Lets examine method #1- matching resistors first. If you choose this method, here are the resistors that must be matched: * 100K - R14 must be exactly matched to 100K - R15 * 100K - R25 must be exactly matched to 100K - R26 * 100K - R36 must be exactly matched to 100K - R37 * 10K - R18 must be exactly matched to 10K - R19 * 10K - R29 must be exactly matched to 10K - R30 * 10K - R40 must be exactly matched to 10K - R41 In addition, the following resistor relationships are necessary to aid with trimming so that shifting on each of the three channels is consistent: * 499K - R27 and 499K - R38 should be reasonably close in value to each other. A difference of less than 400 ohms is best. An exact match is not important. * 499K - R27 and 499K - R38 must be lower in value than R16. The idea is for the value of each R27 and R38 plus their respective trimmer settings (not entire trimmer value range) VR11 and VR12 to be equal to R16 so that each channel's shift tracks uniformly. Since VR11 and VR12 are 1K trimmers, a value for R27 and R38 that is about 500 ohms less than R16 would place VR11 and VR12 near the center of their operating range. None of the other resistor values are critical in the circuit. However, I generally recommend 1% resistors for many locations as indicated in the parts list. Important: If you use the hand match method # 1 for construction of your 831 you must install resistors R14, R25 and R36 in the "B" positions on the circuit board. These are the positions that cover the trimmer install locations. The unused trimmer holes will be covered by these resistors. Nothing is installed in the "A" positions for R14, R25, and R36. Now, let's take a look at method # 2 which involves adding 3 more trimmers to the circuit. (If you plan to use hand matched resistors, just skip this part - to page 3) Measurement of resistors is still important in this construction method. However, the exact accuracy is not required. In fact, if you are not having success with the tracking of your hand matched circuit, I recommend adding trimmers to the circuit. In method # 2, some resistors should still be selected as close matches. Resistors should be selected as follows. * 100K - R14 must be less than 100K - R15 * 100K - R25 must be less than 100K - R26 * 100K - R36 must be less than 100K - R37 The concept is that R14 + trimmer setting value (about 1/2 of trimmer range) must = R15. The same is true for the R25 to R26 and R36 to R37 relationships. Therefore, if you selected a value or R14 that was about 200-300 ohms less than R15, you could use a 500 ohm trimmer. The 500 ohm trimmer should trim out somewhere near mid-range. * 10K - R18 should be closely matched to 10K - R19 * 10K - R29 should be closely matched to 10K - R30 * 10K - R40 should be closely matched to 10K - R41 You need to get these as close as reasonable. The closer they are, the less adjustment is needed in the new trimmers in the input stage buffer / summer. Whether you choose method # 1 or # 2, trimming the effect of the interval switch to be consistent across the channels remains identical. Therefore, just as in method # 1, the following describes selecting R16, R27, and R38. * 499K - R27 and 499K - R38 should be reasonably close in value to each other. A difference of less than 400 ohms is best. An exact match is not important. * 499K - R27 and 499K - R38 must be lower in value than R16. The idea is for the value of each R27 and R38 plus their respective trimmer settings (not entire trimmer value range) VR11 and VR12 to be equal to R16 so that each channel's shift tracks uniformly. Since VR11 and VR12 are 1K trimmers, a value for R27 and R38 that is about 500 ohms less than R16 would place VR11 and VR12 near the center of their operating range. Important: If you use the trimming method # 2 for construction of your 831 you must install resistors R14, R25 and R36 in the "A" positions on the circuit board. These are the positions that do NOT cover the trimmer install locations. The "B" positions are now used for the trimmer installations. Notice that the "4th" hole in the "B" position unused by the trimmer has no connection. ------------ end of skip ------------ Now, that you have your construction method and component selection that out of the way, let's gets started building. We will start by installing the resistors. In these details, I will assume you are using the hand matched method #1, please make appropriate adjustments as detailed above if you have elected to trim your 1-volt-per-octave voltage using method # 2. First, a word about solder. After assembly of quite a few MOTM kits, Paul Schreiber has convinced me that the effort needed to use two different types of solder is well worth while. I always assemble my PCBs now with a washable solder. In fact, I use the same Kester 331 organic solder that Paul supplies with his kits. The instructions for the 831 assembly are written assuming that assembly strategy. PART 1: (Installing the resistors, ferrite beads and filling the via holes) We will use organic washable solder for this part of the construction. * Install a 100K patched pair at R14B and R15 (note R14A remains unused). * Install a 100K patched pair at R25B and R26 (note R25A remains unused). * Install a 100K patched pair at R36B and R37 (note R36A remains unused). * Install 10K matched pair at R18 and R19 * Install 10K matched pair at R29 and R30 * Install 10K matched pair at R40 and R41 * Install 499K, 1% resistor at R16 (should be ~ 500 ohms greater than R27 and R38). * Install 499K, 1% resistor at R27 (should be ~ 500 ohms less than R16) * Install 499K, 1% resistor at R38 (should be ~ 500 ohms less than R16) * Install 33K, 1% resistors (three) at R17, R28, and R39 * Install 5K1, 1% resistors (three) at R20, R31, and R42 * Install 51K, 1% resistors (three) at R22, R33, and R44 * Install 180K, 5% resistors (three) at R13, R24, and R35 * Install 100K, 5% resistors (three) at R21, R32, and R43 * Install 470 ohm, 5% resistors (three) at R23, R34, and R45. This completes the installation of all resistors with the exception of those in the interval-selector resistor-divider network. These resistor values may be selected to any value you calculate to cause the 831 to shift directly to intervals of your choice. The resistor values indicated on the schematic, in the parts list, and on the silkscreen for resistors R1 through R13 will yield the intervals I selected for the 831 prototype. Those selected intervals are: Shift + 5 = up 10 semitones (dom. 7th in same octave) Shift + 4 = up 7 semitones (5th in same octave) Shift + 3 = up 5 semitones (4th in same octave) Shift + 2 = up 4 semitones (major 3rd in same octave) Shift + 1 = up 3 semitones (minor 3rd in same octave) Shift 0 = no shift :) Shift - 1 = down 5 semitones (5th in octave below) Shift - 2 = down 7 semitones (4th in octave below) Shift - 3 = down 8 semitones (major 3rd in octave below) Shift - 4 = down 1 octave Shift - 5 = down 2 octaves The remaining resistor assembly instructions assume you have selected these shift intervals. Substitute your own resistor values as needed. Caution: Notice that resistors R4, R5, and R9 are specified as zero ohms. You need to install wire jumpers across these resistor positions. Because this PCB is two sided and has no solder mask, care must be exercised that the wire jumper does not short to other traces. You can either use an insulated wire jumper at these locations or install the jumper on the bottom of the board. Either is fine. * Install 3 wire jumpers in resistor positions R4, R5, and R9 (see caution note) * Install 2.1K, 1% resistor at R1 (PCB is marked 14K - ignore) * Install 150 ohm, 1% resistor at R2 * Install 51 ohm, 1% resistor at R3 * Install 200 ohm, 1% resistor at R6 * Install 365 ohm, 1% resistor at R7 * Install 68 ohm, 1% resistor at R8 * Install 232 ohm, 1% resistor at R10 * Install 909 ohm, 1% resistor at R11 * Install 953 ohm, 1% resistor at R12 (PCB is marked 13K - ignore) This completes the installation of all the resistors on your 831 PCB. Before the board wash, let's install two more components and fill in our via holes. * Install the two ferrite beads at FB1 and FB2 (read important note first). Important: Unlike resistors and most other components, the ferrite beads are not insulated on the outside. Because there is no solder mask on this PCB, we must be certain that the ferrite beads do not cause any shorts on the PCBs under their mounting location. The PCB ground plane does run right under these components. Therefore, we must add some insulation to the ferrite beads before we install them. I cut lengths of heat shrink just a little longer than the bead itself, slid them over the bead and shrank them. This applied a very nice insulation to the entire bead. Next, we must solder our via holes. There are not many via holes on this PCB that are not at component mount locations. There are 19 very small via holes on the PCB where the traces go to rotary switches A, B and C. OK, this is a good stopping point for our first board wash. Run the board under warm water (do not use any soap or cleaners). Gently scrub both sides of the board to remove the organic flux. Any small brush will do the job. I use an old toothbrush. If you have not done so already, this would be a good point to inspect your solder joints. Check to be certain you have not forgotten to solder one end of a component or that you have not accidentally bridged one thing to another with excess solder. Personally, I check my joints right before I clip my leads. It seems easier to me to find what I have just competed that way. PART 2: (Installing the remaining components on the PCB) When assembling, my preference is to install components by relative height. For example, I find it much easier to install integrated circuits if other taller components have not already been installed. That method is suggested here. However, skip around as you desire. It really does not matter much what order the components are installed in this part. * Install (ten) 0.1uF ceramic capacitors at C9, C10, C11, C12, C13, C14, C15, C16, C17, and C18. These small ceramic capacitors are marked 104. These are located at both ends of each of the five integrated circuit positions. They have no polarity. * Install (five) LT1013 integrated circuits (dual op amps) at U1, U2, U3, U4, and U5. Be certain to insert them in the proper direction. The notch or dot marking pin 1 should face toward the end of the PCB with the ferrite beads. Notice the marking also on the circuit board. All five I.C.s face the same direction. * Install (six) yellow box capacitors at C1, C2, C3, C4, C5, and C6. The marking on the capacitors will be either 1n0 or 102. These capacitors have no polarity. * Install (two) 10uF electrolytic capacitors at C7 and C8. Notice the NEGATIVE stripe on one side of the capacitor. The PCB has a (+) sign on the POSITIVE terminal. Install the capacitor with the stripe away from the (+) pad. Also notice the capacitor lead that goes to the (+) pad is usually longer than the other. The size of these capacitors in not critical. Anything between 10uF and 50uF is fine. * Install (ten) 100 ohm trim pots at VR1, VR2, VR3, VR4, VR5, VR6, VR7, VR8, VR9, and VR10. You will notice the part will install in either direction. It does not matter. They look better if you install them all in the same direction. I placed mine so that the adjustment screw is toward the back of the PCB. I though that might make calibration easier. * Install (two) 1K ohm trim pots at VR11, and VR12. You will notice the part will install in either direction. Again, it does not matter. I placed mine so that the adjustment screw is toward the back of the PCB. * Install the MTA power connector. Notice that the connector has a locking tab on one side. The part is installed with this side facing inside on the PCB. The PCB silkscreen symbol has a line on one side indicating the position of the locking tab. OK, this is a good stopping point for another board wash. Run the board under warm water (do not use any soap or cleaners). Gently scrub both sides of the board to remove the organic flux. This is out last board wash. We will NOT use washable solder for the remainder of construction. If you have not done so already, this would be a good point to inspect your solder joints. Check to be certain you have not forgotten to solder one end of a component or that you have not accidentally bridged one thing to another with excess solder. PART 3: (attaching connecting wires to the PCB) The 831 Interval selector voltage switch must be connected with flexible insulated wire to three front panel switches and six 1/4" phone jacks. No shielded coax cable is required. All of the soldering from this point forward will use no-clean solder. For the remainder of this construction, do NOT use washable solder and do NOT wash the board. * Cut 12 pieces of wire in lengths appropriate to reach from the 831 PCB to your front panel jacks. I suggest using 6 lengths of two different colors to prevent the possibility of error when connecting to the front panel jacks. For the sake of instruction, I have selected red and black. * Solder the 6 lengths of red wire to the ROUND hole furthest from the bottom edge of the PCB for IN A, IN B, IN C, OUT A, OUT B, OUT C. * Solder the 6 lengths of black wire to the SQUARE hole closest to the bottom edge of the PCB for IN A, IN B, IN C, OUT A, OUT B, OUT C. * Twist each of the red and black pairs of wire together. * Cut 33 pieces of wire in lengths appropriate to reach from the 831 PCB to your front panel switches. I suggest using 3 lengths of one color and 30 lengths of a different color to prevent the possibility of error when connecting to the front panel switches. For the sake of instruction, I have selected blue and white. I learned after constructing my very first voltage switch that you will thank yourself if you strip the wire on both ends and tin the ends before attaching to the PCB. This will make attachment to the rotary switches MUCH easier. It is difficult to strip back the wires for attachment to the rotary switches after they are attached to the PCB. Cut each of the wire jumpers 2 inches long. * Solder the 3 lengths of white wire to the A, B, and C pads on the right edge of the PCB. * Solder the or 10 lengths of blue wire to the -5, -4, -3, -2, -1, +1, +2, +3, +4, and +5 pads at the right edge of the PCB at the "A" switch position. * Solder the or 10 lengths of blue wire to the -5, -4, -3, -2, -1, +1, +2, +3, +4, and +5 pads at the right edge of the PCB at the "B" switch position. * Solder the or 10 lengths of blue wire to the -5, -4, -3, -2, -1, +1, +2, +3, +4, and +5 pads at the right edge of the PCB at the "C" switch position. This is another good spot to take a break Soldering all of these wires to the rotary switches will be the most difficult part of assembling your 831. You should be fresh before you continue. Part 4: Preparing the front panel and switches Before installing and wiring the SHIFT switches, we must prepare them for the correct number of positions since they do have an adjustable stop. * Remove the nut and lock-washer for all 3 switches. Remove the adjustable stop and reinsert it so that the movable stop goes in the hole marked "11 Obviously, that means the switch will only have 11 positions available. * I like to bend the rotary switch connections that will not be used flat down on to the back of the switch. This gets them out of your way making it a bit easier to solder to the remaining lugs. You could just break or cut them off. But, that seemed too "final" to me. In this case, you will bend down lugs 6 and 12. * Install the 6 switchcraft jacks onto the front panel. I always install mine in MOTM fashion with the bevel to the upper right corner. The lock-washer goes on the back. * Install the three rotary switches through the appropriate holes in the mounting bracket. Notice the bracket has a hole that exactly fits the turn-stop on the switch so it will not try and turn behind the panel when operated from the knob. The lock-washer should be installed on the switch shaft BEFORE you insert it in though the bracket. * Align the bracket and switches with the front panel and push the switch shafts through the holes in the front panel. Install the 3 switch nuts and tighten. This holds the panel and bracket together. DO NOT OVERTIGHTEN. These are plastic. They do not have to be very tight as the turn-stop secures the switch from undesired rotation. I recommend using a socket from your ratchet set WITH OUT the ratchet. Hold the socket in your hand and tighten the four switch nuts until they feel snug. No more. The bracket should be pulled up next to the back of the panel. The rotary switch turn-stops should still be nestled into their hole. * Attach the PCB to the bracket with # 6 screws and nuts and spacers. Part 5: Attaching the wires from the PCB to the front panel * Connect the OUT A red and black twisted pair from the PCB to the OUT A jack on the panel. The black wire attaches at the beveled lug. The red wire attaches at the left lug. Nothing is attached to the top lug. * Connect the OUT B red and black twisted pair from the PCB to the OUT B jack on the panel. The black wire attaches at the beveled lug. The red wire attaches at the left lug. Nothing is attached to the top lug. * Connect the OUT C red and black twisted pair from the PCB to the OUT C jack on the panel. The black wire attaches at the beveled lug. The red wire attaches at the left lug. Nothing is attached to the top lug. * Connect the IN A red and black twisted pair from the PCB to the IN A jack on the panel. The black wire attaches at the beveled lug. The red wire attaches at the left lug. Also attach a second short wire to the left lug with the red one. The left lug now has two wires. Nothing is attached to the top lug. * Attach the opposite end of this short wire from A IN to the TOP lug of the B IN jack. * Connect the IN B red and black twisted pair from the PCB to the IN B jack on the panel. The black wire attaches at the beveled lug. The red wire attaches at the left lug. Also attach a second short wire to the left lug with the red one. The left lug now has two wires. * Attach the opposite end of this short wire from B IN to the TOP lug of the C IN jack. * Connect the IN C red and black twisted pair from the PCB to the IN C jack on the panel. The black wire attaches at the beveled lug. The red wire attaches at the left lug. Now, let's connect the wires to the back of the rotary switches. * You will start with the wiring from the PCB to switch SHIFT A. All lugs will be connected on this switch except lugs # 6 and 12. Push lug # 6 and 12 over flat on the back of the switch out of your way. You can solder the wires in any order you choose. However, soldering them in order around the switch is not the best approach. Instead, I recommend soldering the wires to the "lower" lugs closest to the PCB first. Otherwise, you will have one heck of a time getting to these lugs and wires once you have wires running over the top of them. * Start with lugs 7, and 8. These are the most difficult to reach. Once you have those two done, the remainder will be somewhat easier. Then, work upwards attaching wires on both sides alternating in a fashion that makes sense to you until you have all wires connected. Yes, they do cross. * Don't forget to connect the white wire to the center lug before you connect the wires across the top lugs 1, 2, and 11. Here is the connection configuration from PCB to the "A" switch lugs: * Rotary switch 1 to PCB - 5 * Rotary switch 2 to PCB - 4 * Rotary switch 3 to PCB - 3 * Rotary switch 4 to PCB - 2 * Rotary switch 5 to PCB - 1 * Rotary switch 6 not connected * Rotary switch 7 to PCB + 1 * Rotary switch 8 to PCB + 2 * Rotary switch 9 to PCB + 3 * Rotary switch 10 to PCB + 4 * Rotary switch 11 to PCB + 5 * Rotary switch 12 not connected * Rotary switch center to PCB "A" * Next you will connect wires from the PCB to switch SHIFT B. All lugs will be connected on this switch except lugs # 6 and 12. Push lug # 6 and 12 over flat on the back of the switch out of your way. You can solder the wires in any order you choose. However, soldering them in order around the switch is not the best approach. Instead, I recommend soldering the wires to the "lower" lugs closest to the PCB first. Otherwise, you will have one heck of a time getting to these lugs and wires once you have wires running over the top of them. * Start with lugs 7, and 8. These are the most difficult to reach. Once you have those two done, the remainder will be somewhat easier. Then, work upwards attaching wires on both sides alternating in a fashion that makes sense to you until you have all wires connected. Yes, they do cross. * Don't forget to connect the white "B" wire to the center lug before you connect the wires across the top lugs 1, 2, and 11. * Use the same PCB-to-switch lug configuration as you did for switch SHIFT "A." * Next you will connect wires from the PCB to switch SHIFT C. All lugs will be connected on this switch except lugs # 6 and 12. Push lug # 6 and 12 over flat on the back of the switch out of your way. You can solder the wires in any order you choose. However, soldering them in order around the switch is not the best approach. Instead, I recommend soldering the wires to the "lower" lugs closest to the PCB first. Otherwise, you will have one heck of a time getting to these lugs and wires once you have wires running over the top of them. * Start with lugs 7, and 8. These are the most difficult to reach. Once you have those two done, the remainder will be somewhat easier. Then, work upwards attaching wires on both sides alternating in a fashion that makes sense to you until you have all wires connected. Yes, they do cross. * Don't forget to connect the white "C" wire to the center lug before you connect the wires across the top lugs 1, 2, and 11. * Use the same PCB-to-switch lug configuration as you did for switch SHIFT "A" and "SHIFT B." Finishing your 831 You have probably realized by now that installing the knobs is all that remains. Rotate all 3 switches counter-clockwise until they are against the stop and will turn no more. Install your knobs so the pointer is toward - 5 on all 3 switches. Rotate these switches clockwise to the 12 o'clock, or no-shift positions. Congratulations ! You are now complete with your 831 construction. Take a moment to inspect your work. Be certain that none of the many wires going to the panel switches are shorting against each other. Make certain that no stray wire strands from you switch wiring are laying on the PCB anywhere. The can short out your PCB since there is no soldermask. Enjoy your 831 module. The 822 and 831 are limited run modules that will not always be available. The first 50 copies of 822 are now sold out. I am making a second run of 50 PCBs, but that will be the end of it. Hidden feature: Because the 831 is limited to 50 and the 822 to 100 copies, I am offering official serial number tags for the bottom of your mounting bracket (or wherever you decide to put it). Serial numbers will be assigned by the order I receive requests Serial #s 001 and 002 belong to me. I am putting this information here only, just to see who actually reads the instructions to this point. Shush.... Mums the word. Drop me a note and I will send your serial numbers right out. Now you are ready for calibration. There are two calibration docs. You do not use both. You use one or the other. One is for those that prefer to calibrate primarily by ear while the other allows full calibration with only a nice voltmeter.