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NOVEMBER -DECEMBER, 1961
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THE LWM-3 -A BANDSWITCHING MOBILE SSB TRANSCEIVER
By W. C. Louden, W8WFH, and A. F. Prescott, W8DLD
PART I - Design and Electrical Details
G -E HAM NEWS is proud to present a complete band - switching SSB/CW transceiver which - though primarily designed for mobile service-is also well suited for oper- ation from a fixed location too.
The LWM-3 tunes eleven 200 -kilocycle wide segments in its over-all range of 3.5 to 30 megacycles. These ranges may be chosen by plugging the proper crystals into the high frequency section which is crystal controlled.
The LWM-3 is a project which the experienced radio amateur can construct and have the equivalent of fine commercial equipment in performance and operating con- venience.
Design and electrical details of this 23 -tube transceiver are covered in this issue, and the complete mechanical and construction details, and tuneup information, are given in the January -February, 1962 issue of G -E HAM NEWS.
The LWM-3 is a MOBILE SSB and CW transceiver cover- ing 3.5 to 30 megacycles, and delivering 5 watts PEP output. It was designed to drive an easy -to -drive linear amplifier.' It features:
1. Transceive operation - no zeroing of the transmitter to the received frequency;
2. 2.1 -kilocycle filter for high selectivity - unwanted side - band down 40 decibels;
3. Double conversion circuit with good rejection of spuri- ous signals;
4. Voice -controlled (VOX) break-in and anti -vox circuits. Plus features include the following innovations:
1. Ultra stable VFO using Command Set transmitter tuning capacitor and packaged oscillator construction for rigidity;
2. Slug tuning unit from broadcast auto radio - modified for ganged exciter tuning control;
3. Custom made slow -tuning rate dial for VFO; 4. Cabinet which is inexpensive and easy to fabricate; 5. Balanced first mixer in transmitter featuring the inex-
pensive G -E 6AR8 sheet -beam tube to minimize spuri- ous frequencies;
6. Standard IF transformers - slightly modified to per- form special tasks;
7. Mobile mount that facilitates "slip in - slip out" opera- tion in the car;
8. Good ideas on circuit board component mounting.
IN THIS ISSUE
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W8WFH DEMONSTRATES here the operation of his new LWM-3 transceiver in his automobile. The complete unit and mounting bracket were designed and built by him and A. F. Prescott, s.V8DLD. The LWM-3 is the latest in a series of projects described by these well-known authors in G -E HAM NEWS. W8WFH drives a pair of 01. -4021/4 -125 -A's in a linear amplifier in his station wagon. Power is supplied by a 3 -phase AC alternator system and high -voltage stepup transformers, as previously described in G -E HAM NEWS.
Basically the LWM-3 was designed for mobile operation. All the "most -used" controls were placed on the left side of the front panel to minimize the distance a driver must reach when tuning and operating the unit. The tubes and associated circuitry were positioned for this placement of the controls.
The size of the unit was reduced to a minimum to prevent using front seat leg room needed by passengers. In fact, three people can still sit in the front seat if the one in the cener sits at an angle with his feet to the right of the trans- ceiver. "VOX" has worked out well through the use of a close -talking reluctance microphone which minimizes back- ground noise pickup.
The 5 watts peak power output is more than adequate to drive the "Mobile Linear Amplifier" even at 28 megacycles. An intermediate amplifier stage with higher power was not needed, and was not included to achieve higher over-all effi- ciency, which is of prime importance for mobile operation. THE RECEIVER SECTION of the LWM-3 transceiver is shown in black in the block diagram, Fig. 1. Several tubes and other key components in the circuit also function when the transceiver is operating as a transmitter. These dual -function stages are colored in red on the block diagram, with the signal paths on "transmit" also in red.
(continued on page 2)
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FRONT -PANEL VIEW of the beautifully constructed LWM-3 trans- ceiver. All controls used during normal operation are at the left, easily accessible from the driver's seat. This model has been seen by thousands of radio amateurs at meetings and conventions during 1961. Panel has brushed aluminum finish.
The LWM-3 -A BANDSWITCHING MOBILE SSB TRANSCEIVER. .page 1
FINAL REMINDER - 1961 Edison Award Nominations page 8
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FIG. 1. COMPLETE BLOCK DIAGRAM of the LWM-3 transceiver. The diagram is color coded to show: (1) circuits which operate only on receive, and inoperative on transmit, are in solid black lines; (2) circuits which operate both on receive and transmit in solid black and red lines: and (3) circuits which operate only on transmit in solid red lines. The schematic diagram number is marked next to each tube and component.
(continued from page 1) A 6BZ6 remote -cutoff pentode (VD)
serves the dual purpose of tuned RF amplifier for the receiver, and as the driver for the output amplifier on transmit. The amplified incoming signal is then mixed in a 6BA7 pentagrid con- verter (V,5) with the signal from the crystal oscillator (V,0), a 6BZ6 pentode, resulting in an intermediate frequency signal between 2.955 and 3.155 mega- cycles.
This IF signal then passes through passband tuned circuits in T, into a second 6BA7 pentagrid converter (V,,), where the signal is mixed with the 2.5 to 2.7 -megacycle VFO signal from the tunable oscillator (V2). The difference signal in the output of the second mixer in the 450 to 460 -kilocycle range, is then fed through the 2.1 -kilo- cycle wide mechanical filter (FL,D,). This second IF signal is amplified in two 6BA6 remote -cutoff pentodes (V.. and V25).
Demodulation of SSB signals is ac- complished with a 12AU7-A twin tri- ode (V.,), which functions as a product detector. A 6AU6 crystal controlled beat frequency (BFO) oscillator (V0) provides the inserted carrier for the product detector. Two crystals, Y, and Y., place the oscillator on the correct frequencies for selection and reception of upper or lower sidebands. After de- tection, the audio signal is amplified in a 6GH8 pentode section voltage amplifier (VA,SA) and a 6AQ5 beam power audio output stage (V,3).
THE TRANSMITTER SECTION of the LWM-3 utilizes a 12AX7 twin triode as two stages of audio amplification (VIA and V,e) from a high -impedance microphone input (J.01). The audio sig- nal is then fed into a balanced modu- lator (four 1N34 -A diodes) through the triode section of a 6U8 -A (VSA) in a cathode follower circuit. The same BFO (VS) used for the receiver drives a 6U8 -A pentode section isolation ampli- fier (Y.B) to supply the carrier to the balanced modulator. Crystals Y, and Y. again provide selection of upper or lower sideband.
The output of the modulator is a
double sideband suppressed carrier sig- nal, the carrier having been balanced out in the modulator. This signal passes through the 2.1 -kilocycle bandwidth mechanical filter (FL,e,) at 455 kilo- cycles to remove one sideband. The resulting single sideband signal is then amplified in a 6BZ6 pentode (Ve) before being applied to a 6AR8 sheet beam tube (V6).
The 6AR8 mixes this SSB signal with the signal from the VFO (2.5 to 2.7 megacycles), resulting in a signal in the 2.955 to 3.155 -megacycle range, de- pending upon the frequency to which the VFO is set. After passing through the bandpass filter (T, and T.), the signal is mixed with the signal from the 6BZ6 pentode crystal oscillator (V,0) to arrive at the desired amateur band output signal frequency.
Then the signal is amplified by the 6BZ6 RF amplifier (VD), and this stage, in turn, drives the 12BY7-A beam pentode (V,1) output amplifier. Thus, the RF amplifier, VFO, BFO, and the crystal oscillator tubes, plus the 2.1 - kilocycle wide mechanical filter and the 2.955 to 3.155 -megacycle bandpass filter, all serve dual purposes in the LWM-3 and function both for reception and transmitting.
Still other circuits in the LWM-3 transceiver include automatic volume control (AVC) (V,0), an "S" meter circuit (y..), and a 100 -kilocycle crystal calibrator (V12) to provide precise fre- quency markers from which to adjust the tuning dial pointer.
Most of the circuit switching be- tween receive and transmit is per- formed by applying a minus 65 volts - obtained from the external power supply - to the tubes which are un- used in each function, biasing these stages to cutoff condition. This is sim- pler than transferring such functions through relay contacts or other me- chanical means.
The voice -controlled break-in (VOX) circuitry (V10, V,., and V100) actuates three relays during transmit which ap- ply and remove a minus 65 volts to appropriate circuits. Plate and screen voltage is applied to V.A and V3 only during transmit. One of the control
relays also transfers the antenna from the input circuit of VD to the output circuit of V during transmit. THE SCHEMATIC DIAGRAMS of the LWM-3 transceiver have been divided into sections according to major func- tion to facilitate reference. Major com- ponents in the transceiver are identi- fied in the photo on page 3.
The transmitter schematic diagram, Fig. 2, contains the circuits of the two key oscillators, the VFO (ye) and the high -frequency crystal oscillator (V10). A description of these circuits follows.
The heart of any mobile communica- tions unit is the tunable oscillator (VFO), and therefore the design of the LWM-3 was built around this unit. It was realized that stability was the prime objective and small size would necessarily be the second. From previ- ous experience with mobile VFO's the LWM-3 VFO was designed to with- stand shock and impact testing as well as vibration and thermal drift.
A series -tuned Colpitts (Clapp) cir- cuit using the Harrington XL -1 coil (L200) and a Command Set transmit- ter tuning capacitor (C205) resulted in the desired frequency stability after a series of preliminary tests. All major frequency determining components were bolted directly 'to the capacitor frame to eliminate relative movement of parts. A temperature compensating capacitor (C204) in conjunction with a zero drift (C203) is used to compen- sate the VFO for the temperature rise within the transceiver cabinet during operation.
The oscillator output is divided by a 470-microhenry coil (L202) in series
s"MOBI LE LINEAR AMPLIFIER," G -E HAM NEWS, November -December, 1960 (Vol. 15, No. 6). This bandswitching amplifier has two GL -4D21/4 -125-A tetrodes in parallel and covers 3.5 to 30 megacycles. 2Jockson, "Coils for the HF Crystal Filter," DST, June, 1960, page 63. This text says: - in selecting matched germanium and silicon di- odes, the normal ohmmeter reading does not seem to be accurate enough, but the forward current flow through a diode from a 11/2 -volt floshlighl battery source will show up minute differences in the forward resistance of various diodes. Out of a group of 20 I
found four in which the current flow varied only S percent. Used in a ring modulator, these provided ap- proximately 40 db. of carrier suppression with no attempt made at balancing the modulator."
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TOP VIEW OF THE LWM-3 showing the location of major com- ponents and the tubes in the unit. Packaged VFO is large assembly at left -center behind panel. Crystals which select the 200 -kilocycle tuning segments are at right. Mechanical actu- ator for ganged slug -tuned coils in the RF amplifier/driver
with a 12-microhenry RF ,coil (L203), to provide between 1.2 and 1.5 volts RF for the first transmitter mixer (V,) and second receiver mixer (V,,).
The crystal oscillator is a standard electron coupled Pierce circuit which uses fundamental crystals. The output circuit is tuned to the marked fre- quency of crystals in the range from 3.5 to 12 megacycles. Above this the second harmonic of the crystal is ob- tained in the oscillator plate circuit, pretuned to each crystal that is selected by the bandswitch (Ss.5).
The plate coil, L212, could be gang tuned with the RF amplifier and possi- bly eliminate some of the trimmer ca- pacitors selected by S,n. The series plate resistor (R225) can be adjusted so that the oscillator will provide 2.0 volts RF for the transmitter second mixer (V,), and the receiver first mixer (V,,). The value of 4700 ohms for R225 gave the correct voltage in this unit.
The 6AR8 sheet beam tube (V,) in the transmitter first mixer has the RF signal from the VFO applied to the control grid, and the 455 -kilocycle SSB signal from the generator section ap- plied to one beam deflection plate (see "D"). No balancing voltage controls
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stage (V,) is at right -center; was originally a push button tuning mechanism from an auto radio. Detail views of the bottom will be published in PART II of this article. All 23 tubes (count 'em) are clearly visible on the chassis. Note en- closed relays K2 and K,.
were found necessary for the deflection electrodes of the 6AR8 to obtain satis- factory rejection of the VFO signal in the output. Several 6AR8 tubes with unbalance were substituted in the cir- cuit to confirm this fact.
A Miller type 6205 4.5 -megacycle ratio detector transformer was used for the balanced output transformer. This transformer has a tertiary wind- ing which must be disconnected by un- soldering its connection to pin 6. An additional transformer (T,), a Miller type 6203 4.5 -megacycle IF trans- former, is used to obtain the desired bandwidth to cover 3.155 to 2.955 mega- cycles with high attenuation outside this range. The secondary of T, is used as a parallel tuned trap to help attenuate unwanted frequencies.
The output of the bandpass IF ampli- fier is connected to a second balanced mixer - a 12AT7 (V,) twin triode - of conventional design. Both mixers are biased to cutoff when the trans- ceiver is in the receive function.
The grid and plate circuits of the 6BZ6 pentode RF amplifier (V,) are slug -tuned circuits with various capac- itors switched in parallel to resonate at the various amateur band segments
selected by the bandswitch. The plate circuit is also the grid circuit of the 12BY7-A pentode final amplifier (V). Bridge neutralization is used and a Pi - type output network with 50 -ohm out- put impedance is band switched in the plate circuit.
Since the 12BY7-A is operating class A, a Pi output tank is quite inefficient but it is a simple unit to switch, and provides sufficient RF output to drive W8WFH's mobile linear amplifier. A 1N34A diode (CR,) voltmeter circuit is provided across the 50 ohm output to facilitate tuneup procedures. THE RECEIVER SECTION schematic dia- gram is shown in Fig. 3. This diagram contains the AVC, "S meter and crys- tal calibrator functions. The 6BZ6 pentode RF amplifier for the receiver (See V, in Fig. 2) -also the RF driver stage in the transmitter - receives the signal from the antenna through con- nection "W" and the antenna transfers contacts on relay K,, in the VOX AND CONTROL CIRCUITS schematic dia- gram, Fig. 5. The plate circuit of V, then runs to the 6BA7 pentagrid first receiver mixer (V,5) in Fig. 3 through connection "U."
(continued on page 6)
TRANS
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0228 8- 50 C230 8.50
C229 50
C2311 C235 240,1 Z1000
C232 "" C233 ,7, 8.50,x, 680
R216 100 K
8217 470K
1.207
C236 aUF L208
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R219 68
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C246 f 220 1,
C247 01
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8207 470 K
4215 } 00
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4221 476
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TABLE I - COIL TABLE
1,04, L,o:, 13,4, 1008, 1:11, tor, lo1n....220uh RF coil (1. W. Miller 4646-E).
11o,, Lan, 1,4,....2-Mh. RF coil (J. W. Miller 4666-E). Llo4...-480 - 800-uh adjustable RF coil (Cambion 156-CN2L,
or J. W. Miller No. 4514-1). 1100....18-uh VFO coil; 52 turns, No. 24 tinned wire, wound 28
TPI, 17/4 inches long, on 3/4 -inch diameter grooved ceramic coil form (Harrington Electronics No. XL -1 coil).
Lro,....4 - 6-uh slug -tuned coil; 22 turns, No. 24 Formex wire close wound on 3/4 -inch diameter form (Cambion LS -5 blank form).
Ls, 1, 1....470-uh RF coil (J. W. Miller No. 4649-E). 1704....1 2-uh RF coil (J. W. Miller No. 4624-E). - 3.0-uh slug -tuned coil; 18 turns No. 26 Formex
wire spacewound 1 inch long on 0.354 -inch diameter fiber form;' 3 turns No. 26 interwound at grounded end turn spacing decreases from '/4 inch to 1/32 inch (simi- lar to Collins Rodio Co. No. 544-9715-002 coil).
L7o,, L4,4....6 turns No. 26 Formex wire on 47 -ohm, 1/2 -watt composition insulated resistor.
L,00....0.5 - 3.0-uh slug -tuned coil; 13 turns, No. 26 Formex wire, space wound 1 inch long on same form as 1.04;
Vf0 TO 2ND RCVR MIXER 2
turn spacing decreases from 1/2 inch to 1/32 inch at lower end (similar to Collins Radio No. 544-3135-002).
L:7,....0.3-uh, 5 turns, No. 20 tinned wire, 1/2 -inch diameter, 5/16 -inch long, 16 TPI (B & W 3003 Miniductor).
Lc12.-0.8 - 1.5-uh slug tuned coil; 10 turns No. 24 Formex wire closewound on '/4 -inch diameter ceramic form (Cam- bion LS -6).
1_,s....0.6-uh, 8 turns, No. 20 tinned wire, 1/2 -inch diameter, 1/2 -inch long, 16 TPI (B & W 3003 Miniductor).
1716....12-uh total, 64 turns No. 24 tinned wire, 1/2 -inch di- ameter, 2 inches long, 32 TPI, tapped at 9 (21 Mc.), 18 (14 Mc.) and 32 (7 Mc.) turns from L_Is end (B &
W 3004 Miniductor). L:Is....33-uh RF coil (J. W. Miller No. 4628-E). L7o1, L,n- 1.2-uh, 12 turns No. 24 Formex wire closewound on
1/4 -inch diameter ferrite core.
'Forms for 1106 and L.,r, are impregnated paper fiber, 0.354 - inch outside diameter, 0.260 -inch inside diameter, 13/4
inches long, tuned with 1/4 -inch diameter ferrite slugs 1'/4 inches long with flexible drive rod (similar to Collins Radio Part No. 288-2509.00). Coil forms and tuning slugs are available from Jeff-tronics, Unlimited, 4722 Memphis Avenue, Cleveland 9, Ohio.
FIG. 2. "TRANSMITTER" SECTION schematic diagram, showing the tunable oscillator (Vs) (VFO), high -frequency crystal con- trolled oscillator (V,o), and RF amplifier (V4) circuits which operate both on receive and transmit. The two transmitter mixers (V4 and V,), and the final amplifier (V) operate only on transmit. The BANDSWITCH (S0) is shown in the highest frequency position.
IN ALL SCHEMATIC DIAGRAMS, resistances are in ohms, tolerance ± 10 percent, 1/2 -watt power rating, unless other- wise noted. Capacitances marked "UF are in microfarads, disc ceramic type unless otherwise described in the PARTS LIST. Capacitances not marked "UF" are in micro-microfarads (mmf), and mica type unless otherwise noted. Inductances are in microhenries unless otherwise described in PARTS LIST. Connections which run between schematic diagrams Figs. 2, 3, 4, and 5 are coded with letters "A" through "II" where they enter and leave each diagram. Only two inter -diagram connections are coded with each letter, except code letters in circles, which have three or more connection points. Components connected to panel controls are identified with the control title in a rectangular box.
TABLE II - PARTS LIST C,77, C72c, C776, C73,, C777, C,,, C,18, C747, C:,., C_56, C:66,
C240, C,1- 8 - 50-mmf midget variable ceramic. C7o7....200-mmf NPO ceramic (two 100-mmf NPO's). ,5ám....4.5 - 25-mmf midget variable ceramic (Erie TS -C). - 30-mmf midget variable ceramic (Erie 557-F). Cm....5 - 25-mmf double bearing variable (Front tuning ca-
pacitor from 2.1 - 3 -Mc. Command Set transmitter). Cz«....100-mmf NPO ceramic (Erie TCO-100). C202, C,.4 1200-mmf silvered mica, 500 volts working. C210, C7z,. C,,s, C,,,, Cm,....5-25-mmf midget variable ceramic. C211, C,.. 200-mmf silvered mica, 500 volts working. C214, C_, 62-mmf silvered mica, 500 volts working. C222, C,,,, Coss....50-mmf, 500 -volt silvered mica. C731, C211, C,,1....240-mmf, 500 -volt silvered mica. C2s3, C245, C24,....680-mmf, made from a 330 and a 390-mmf,
500 -volt silvered mica in parallel. C,09....240-mmf silvered mica, 500 volts working. C270....390-mmf silvered mica, 500 volts working. C,21....680-mmf silvered mica, 500 volts working. C222....1000-mmf silvered mica, 500 volts working. C2:2....1800-mmf silvered mica, 500 volts working. C2-4....10 - 140-mmf midget air variable with 1/4 -inch di-
ameter shaft (Hammarlund APC-B-140, of HF-140). Cz:s....1.5 - 7-mmf midget variable ceramic (Erie 557-A).
TO L TO MIKE INPUT
TO F ,. To MONITOR TONE
TO K TO TONE OSC.
TO I To 2.1 KC FILTER OUTPUT
TO k TO VARIABLE IF OUTPUT
TO R TO VF0
TO N _.TO 2.1 KC FILTER INPUT
TO T TO KTAL OSC
TO TO RF AM PL
To vAINA8LE IF .1.C403 70 T 1ST RECEIVER
... 470 HIRER
V15 R402 6847 9 1006 G R403 IOOK
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2ND RECEIVER MIXER
R405 33K
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CR,, CRz, CR,, CR,....matched set of 1N34A germanium diodes. FL,o,....455-Kc. mechanical filter, 2.1-Kc. bandwidth (Collins
F-455 J21). 1:....6.3 volt, 0.25 -ampere pilot lamp (G. E. No. 46). J,, Jz....chassis type midget coaxial cable connectors. J3....midget phono type 1 -pin jack. J,o,....midget 3 -way phone jack (Mallory SCA-2B). K,....4 pole, double throw midget relay, 10,000 -ohm DC coil
(P & B GB -17D). K,, K,....4 pole, double throw midget enclosed relay, 110 -
volt DC coil (P & B MG-17DP, or Phil -Trot 9DC-115-4C). L....See TABLE I - COIL TABLE, for specifications of all coils. M,oá....0 - 1 -Ma. DC midget panel meter (Lafayette). P3o1....24-pin midget type male connector with chassis mount-
ing flange (Amphenol 26 -4101 - 24P). R,,:, Rs, Rl.s....500,000-ohm potentiometer (IRC 013-133). R13. 100 -ohm Trimit 10 -turn potentiometer (Bourns 273). 8926....50,000 -ohm potentiometer (IRC Q11-123). R210....10,000 -ohm potentiometer (IRC 011-116). R410....2,500 -ohm potentiometer (Clarostat A47 -2500-S). R,,, 75,000 -ohm potentiometer (Clorostat A47 -75K -V). R,á, 500 -ohm Trimit 10 -turn potentiometer (Bourns 273). R425 500,000 -ohm audio taper potentiometer. S2....6 pole, 5 -position three section phenolic insulated minia-
ture tap switch (Centralab PA -1020).
XTAL CAL
S 7 pole, 11 -position, seven section, miniature ceramic in- sulated tap switch (Centralab PA -302 Index and seven PA -1 2 - 12 -position non -shorting 30 -degree wafers).
S,....Double pole, double throw midget slide switch. T,....4.5 -megacycle Ratio Detector type IF transformer with
tertiary winding disconnected (J. W. Miller 6205). T. 4.5 -megacycle input or interstage television IF transformer
(J. W. Miller 6203). T3....455 -kilocycle input type IF transformer; secondary de -
tuned and not used (J. W. Miller 12-C1 ). T4....500 -kilocycle output type IF transformer. Ts Audio output transformer, 5000 -ohm primary, 4 -ohm
secondary, 5 watt power rating (Stancor A-3877). V, to Vzs....General Electric receiving tubes, types as marked
on schematic diagrams. Y1 -. Quartz crystal, 453.9 kilocycles, FA -5 type holder. Y- Quartz crystal, 456.4 kilocycles, FA -5 type holder. Y3 to Ys3....Quartz crystals, see TABLE Ill - CRYSTAL CHART,
for frequencies. Loh_ 11 -volt, 1 -watt Zener diode (G. E. Z4X11B).
FIG. 3. RECEIVER SECTION schematic diagram for the LWM-3. All circuits in this section operate only on receive, except the "S meter amplifier (Ve), which also functions as an ALC voltage indicator on transmit.
CALI US80 d{W 0 O 0 b 0 O
LS80--p 0 o-p ° 0+-q o o- 11 TUNE j
II
I
SIA 518 7SIC SID
II8421 MÉCv
V19 C415 6AU6 1000 C416
02UF l77
R423 2206
L400 220
6
42 21 C416 MEG TOIUF
I00 KC
41
v01ECT C420 AVC ISCLATICN
330 0206
.+. 2424 -} 2200 \
-C419 100
226
S METER 022
12Áu7 -A
2
6432 2200
e
R434 330
R433 500 77, ADJ
o ¡Áv6 IALC
TORFAMPL TOx
TO ALC-AVC -TO S
S METER M401
33
C436 DIUF
TO FINAL TO P
-650
l0urvurl
R425 75 K
INF GAIN I
R426 1500
6442
AVC
GRO ON RCV AA
OD
1_1,554061F 1,5406 56UF
R409 1006
C407,LR410 AluF2500
e
6411 TOOK
IST I -F AMPL
S V17 6846
47K
9oluF ,5408
3 _-1 II
i ' I
.-JC410 500 T
-11 C409
2414rr7.01UF 2200
8413 826
290 1-F R415 AMPL 4706
V,8 6846
2
74
5 p416
6
47K
,5411
¿412 T2417 20C OIUF1
-65V CN TRANS FIFO
CC
T0{
R419 wao áüc 6418 47K
0413 PUF
PRODUCT
DETECTOR
1211j74, 0421
10
-It-r7 - l I és3 -Íc42e22 R427
IpOK
425 T N7 IUF
R429 I R42 820
10423 JUF
R430 330X
L401 2M 14 7... 0426
56 4 -II --
C424 - 220
2207 1
8431 476
C429 2200 -{-- (AF GAR
i
0428 570 Ih
1ST RCVR AUDIO AMPL
VI34 t 6GR8
¡ 2
R435 5000
5000
6438 R439 RCVR
220K 2706 OUTPUT AMPL 023
6A 05
0432 1UF
330037 4 C431 25UF
R440 R441 270 .104 34
T 25UF
88
T5
RN
n
47
48
R420 106 SW
MONITOR TONE
*265V
2N0 KMTR
1ST KMTR AUD10 AMPI
J01 VIB
0E L100 V" h 1 C107 1
i 12AX7
220 12,%7 I ,i RNG_.___. _ _ l
ANW 3 R2033
CK,9 7
6
PDo 00 500}I
r%16 T R R102 680
0114
F--1t' 500
C108 iF+ Ur
IpOK CIIO IVICI y1 G,.1 RIIB
CO. 500
8106 615K IMEC Rill
2 0103 476
MO/h 1010O
430
Lele -3 455 KC SIDE8AN0 GENERA -0R
0101 { 220K
0105
470K IRI/I 07
Il r I( It- ose
R108 $8109 5RIK3 04
2700 2 206 2 688 6
C104 68
,
a113 1000
8112 008
0106
8117 500«
SOOK
CCI 01
RING I
+ 1108 I
IIGAIN
4706
VOX y OFF
ION 8117)
04114 FOL
v2A 6U8
-a
C113 .01
--- C114 .SUF
C121 BALANCED 24 14o01.UTa1
L101 2R R IN544
220
9 Cp20
R122 4700
CR,
C122 WC 8.50
265 V
265 ON TRANS TNAI RELAX CTS C
C129 220w,1111« R131 I II O. 1
Rí®0 32 100
8155 330
C130 220
F 610 2,1 KC
J 1Cí51 Y:132
-01 100
aNIj 1000
R134$ 100K
0153 800
45514 R137 AMR 3,K v5
6826y
C215
1 .OI
R135 68
TO 1ST un,KER 1RANy1TTER
? 0."<R138 R136 AI 12200 68K
TO U06 AWL
8F0 v3
6AU6
8123 S C115 688
r1
1 d
R128 10118 330K .01 ,14 BFO
KKKt. Y28 1501.4TiON i 608 43/PL (-- A¡¡ 0123 /ry CIZ16
1000 "t5 1
Ip2S0it
220K C124
CI16 - +220
R127 1000 ' 220
r-:,71, IONE
PART OF
Slr
D2,1 8129 a T 006
1.102 220
C7 1 G28
RISK TSOO
TO RCVR IST AIOq NIP F
aroON TR MI5 -65ONR,G
ALC OR AVC
TO 21,0 RCVR MIXER N
TO RCVR IF AMP
FIG. 4. SSB GENERATOR schematic diagram, showing the transmitter audio section (V,, VoA and V.4), and BFO isolation amplifier (Van), diode balanced modulator (CR4 to CR4), and 455 -kilocycle amplifier (Vs), which operate only on transmit. The BFO (V,) and mechanical filter (Fl,.,) operate both on receive and transmit.
(continued from page 3)
A signal from the high -frequency crystal oscillator (V,. on Fig. 2) through connection "T" is mixed with the received signal to obtain a signal in the bandpass first IF range, 2.955 to 3.155 megacycles.
This IF signal then runs back through connection "Y" to Fig. 2 and through transformer T,.- From T1, the signal runs back through connection "R" to Fig. 3 - transformer T, is not used for reception - to the signal grid of the 6BA7 second mixer (V..).
The VFO signal from V, in Fig. 2 is fed into V,. through connection "Z," converting the first IF signal down to approximately 455 kilocycles. This sig- nal then exits to Fig. 4 through con- nection "H" to the 455 -kilocycle me- chanical filter (FL.). From FL,., the signal returns to Fig. 3 through con- nection "I" and runs through a con- ventional two -stage IF amplifier.
At the output of the 455 -kilocycle IF strip, the full output voltage is applied to the 6AL5 twin diode AVC Rectifier (VW. Through a capacitive voltage divider made up of C421 and C422, part of the IF voltage is applied to the 12AU7-A twin triode product detector (V). A conventional first audio - 6GH8 pentode section (VITA), and 6AQ5 power pentode second audio am- plifier (V) is used.
A 12AU7-A twin triode (V2.) in a balanced VTVM circuit is used with a 0-1 milliameter (M,.,) to read the AVC voltage on receive or ALC voltage on transmit. The same meter is used as an output meter on transmit through a DPDT slide switch (S,) on the front panel. A 6A136 -A pentode (17,0) tube in a 100 -kilocycle crystal oscillator is used to calibrate the receiver.
THE 55B GENERATOR section, includ- ing the audio circuits, is shown in the schematic diagram of Fig. 4. Connec- tions which run from one schematic di- agram to another are identified with the same code letter where they leave one diagram and enter the other.
Input from a high -impedance micro- phone (J,m) runs through a two -stage audio amplifier using a 12AX7 twin triode (V,). A cathode follower stage - the triode section of a 6U8 -A (V,4) - feeds the audio signal into a diode balanced modulator. The audio stages have coupling and shunting capacitors which shape the frequency response to the 300 -3,000 -cycle speech range.
The MICROPHONE GAIN control (R116) is between the 12AX7 and the 6U8 -A. Audio voltage for the VOX system is tapped off at this point through the VOX GAIN control (RT). It runs to the VOX section on Fig. 5 through connection "E. A 6U8 -A pen- tode section (V.A) functions as a tone oscillator to provide an audio signal for tuneup purposes.
The audio signal from V.4 feeds into a ring type diode balanced modu- lator with four 1N34A germanium diodes. These were selected to have nearly identical forward resistance using the method suggested by W3NMP.' Some juggling of C121 may be necessary to make the modulator null out the carrier within the adjust- ment range of C122. A miniature Bourns Trimit, 10 turn potentiometer (R132) was found to provide good car- rier null and to hold its adjustment with mobile vibration.
The 6AU6-A BFO crystal oscillator (V.) provides a signal of either 453.9 or 456.4 kilocycles, depending upon whether crystal Y, or Y, is connected,
TO P80D1K:T DETECTOR .1
TO Se K
TO Si
through a 6U8 -A pentode section (V00) isolation amplifier to the balanced mod- ulator. The output of the modulator, a pure 455 -kilocycle DSB signal, is con- nected to the 2.1 -kilocycle bandwidth mechanical filter.
Output of the filter is amplified by a 6BZ6 pentode (VS) to increase the level to several volts RF for the 6AR8 balanced mixer (VII). The signal patch to V. runs through connection "D" to the left side of Fig. 2.
THE VOX and other control functions in the LWM-3 transceiver are combined in one schematic diagram, Fig. 5. The audio signal from the microphone, amplified by V, in Fig. 4, is transferred to the VOX circuit through connection "E." This signal is further amplified in a 6U8 -A triode section (V.n). It is applied to one diode of a 6AL5 (V,24), rectified and charges capacitor C,.R posi- tive. This positive charge causes the 6GH8 triode section (V0) relay actu- ator stage to conduct more plate cur- rent, energizing relay K,. In the ab- sence of audio voltage, C,.. discharges slowly through R. and R,.T, causing V0 to conduct less current and de - energizing K,.
An anti -trip circuit to prevent speak- er noise from triggering the VOX cir- cuit obtains an audio signal from 6AQ5 audio amplifier (V..) in Fig. 4 through connection "BB. This signal is recti- fied in diode V0 and develops a nega- tive voltage which counteracts the posi- tive voltage developed when noise from the speaker is picked up by the micro- phone, and which otherwise would actu- ate the VOX circuit.
An Automatic Load Control (ALC) circuit is incorporated into the trans- ceiver by which an RF voltage from an external linear amplifier is fed into
J_
TOBB
TO CC TO D0 TOEE TOFF
TO GG
TO88 TOII TO® TO V
VOX ANN. VOK RECT 8300 V413 C307 VI2A 47K 16U8A AIUF i6ALS
-YWY- OOK R301 IMEG
8302 IK
C30 O0111:6
L WM3 VOX AND CONTROL CIRCUITS
ANT -TRIP RECT
9120 .V12 GALS
5304 82MEG
R305 2MEG 0307 8. 1
10 MEG
65 ON TRANS
AVC T CONNECTED NO ALC FROM TRANSCEIVER
R111. 2-.C.1119,IUi9
10
[ANTI-TRIP]
NOTE: C300 4306 .01ÚF
00 C 1 C302 e303 C304 C305 C306
b b b 2 3 4
SPARE PINS
b ó O 5 68 jls o p o
V2 6088 VOX RELAY ACTUATOR
VISO
25ÓK
C310
VI /1d2 á
Í
O d
M
Ñ Ñ Pí01 = z
W Ca
02 < áa
FIG. 5. VOX AND CONTROL CIRCUIT schematic diagram. The heater circuit for all 23 tubes is shown at the left side of this diagram. All tubes in this section operate only on transmit. Antenna transfer and power control circuits are in
a time constant network and V through J,. This voltage is applied to the 6BZ6 driver amplifier (V. in Fig. 2), and the 6BZ6 455 -kilocycle IF amplifier (V,).
One set of SPDT contacts on relay K, in the LWM-3 transceiver trans- fers the antenna from the receiver to the transmitter when it is energized. The antenna connection from K_ to the receiver also runs through a set of SPDT contacts on K,. These contacts remove the antenna from the receiver and ground its input during transmit.
No external antenna transfer relay or T -R switch is thus required when the LWM-3 is operated directly into an antenna suitable for transmitting. However, when the LWM-3 is used to drive a linear amplifier, a coaxial cable should be run from the receiver con- nection on the antenna transfer relay or T -R switch for the linear to J, in Fig. 5. Or, if a separate receiving an- tenna is used, connect it to Ji. MOST EXTERNAL CONNECTIONS from the LWM-3 run through a 24 -pin plug (P.) on the rear of the chassis. In addition to the power connections on pins 1 through 8, provision has been made to control some external func- tions from within the LWM-3. The connections from pins 9 through 15 run through a section of the bandswitch (S20). This circuit can be used to con- trol external functions - linear ampli- fiers, etc. - for each band.
Pins 16, 17 and 22 connect to SPDT contacts on K2, permitting control of an external function on either transmit or receive. Also, pins 23 and 24 connect to another set of SPDT contacts on K_ which have the movable contact arm grounded, permitting external circuitry to be grounded in either position of K:. All pins on P,B, are bypassed to the
.OIUF
2301
1.300 C311 220 ,IuF
J3
PART OF S2 - SEE TRANSMITTER
A
R30. 100
0 Ate lZERO
R i IOOK315
312 AIUF
Via GALS
6801
C316 1 O9
r 010 C317 A
II
52G C310 A
NOTE:C316-C327 AIUF
AVC
ALC SECT
CSIa 3300
Csi3 OIUF
C315 a37UF
26S
-45V
ALC
C319
C320
C321
C322
C12S
C326
C327
I A Kl
R31 4 4700
Ja fir OUT TO FINAL
COMM AUX.
BON AUX.
40M AUX.
20M AUX.
W W V AUX.
ISM AUX.
IOM AUX.
TO COMM, ON RCV
COMM.
OTON TRAN COMMS.
GRD ON RCV
GRO ON TRANS.
P 301
TO O
pTO W
TO C
TO5
TO G
the upper right hand corner of the diagram. All sets of contacts on control relays are shown in their de -energized, or receive, position. Connection is made to J, to drive a linear amplifier from the LWM-3 transceiver.
chassis by capacitors C. to C:W6, and C. to G_;) to prevent RF leakage out- side the LWM-3 enclosure.
The LWM-3 requires 265 volts DC (not less than 240, or over 275 volts is recommended) at about 200 milliam- peres, and minus 65 volts at 10 milli- amperes for bias. The tube heaters are arranged in a series -parallel circuit for either 6.3 or 12.6 -volt operation. A 12.6 - volt, 4 -ampere source can be connected to pins 2 and 5 on P,B,; or, a 6.3 -volt 8 -ampere source should be connected to pins 2 and 4, and pin 5 should be con- nected back to pin 2, thus placing all heaters in parallel.
Informationon an AC power supply for the LWM-3 will be covered in PART II in the next issue. This sup- ply - or a mobile power supply - can be turned on and off through connec- tions to pins 6 and 8 on P195. These connections run through "GG" and "II" to Fig. 3, the receiver diagram, where they terminate in S,D,, a switch mounted on potentiometer R3, the AF GAIN control. CRYSTAL LATTICE FILTER -
Although the LWM-3 transceiver as
designed, described and constructed uses a Collins F -455J21 mechanical filter, it is possible to substitute a crystal lattice filter for it. The crystal lattice filter usually will not have the sharp selectivity of the mechanical filter, and thus the selectivity on re- ceive, and unwanted sideband attenua- tion on transmit, will not he as good.
A representative circuit for a full lattice filter is shown in Fig. 6. Inex- pensive war surplus type FT -241-A crystals can be used in a 455 -kilocycle filter of this type. Refer to the "Filter System" chapters in thé sideband hand- books for complete information on cir- cuits, construction and, most important, proper alignment of crystal lattice filters. MECHANICAL DETAILS -
Complete mechanical and construc- tional details on the LWM-3 will be published in PART II of this article in the January -February, 1962 issue of G -E HAM NEWS.
Now that you've covered the design and electrical details, start collecting parts and be ready to start construc- tion when the next issue is out!
FIG. 6. FULL CRYSTAL LATTICE FILTER schematic diagram. This type of filter con be substituted for the Collins mechanical filter in the SSB GENERATOR schematic diagram, Fig. 3. Certain circuit changes may be necessary, as described in the chapters on filter systems in handbooks on single sideband.
FINAL REMINDER -1961 EDISON AWARD
NOMINATIONS CLOSE JANUARY 3, 1961
Nominating letters for the 1961 Edison Radio Amateur Award must be postmarked not later than Janu- ary 3, 1962.
Please remember that the judges «ill consider only candidates whose names are submitted in writing by you and others. There is no other source for Edison Award nomina- tions.
Therefore, between now and Janu- ary 3, canvass in your mind the ac- tivities of amateurs you know, in order to make sure no deserving OM or YL fails to be represented. If you uncover such a candidate, by all means send in his name promptly.
Write to Edison Award Committee, General Electric Co., Electronic Com- ponents Division, Owensboro, Ky.
HERE ARE TYPICAL ACTIVITIES THAT CAN QUALIFY FOR THE AWARD: Emergency communications work in a dis- aster, such as a flood, hurricane, tornado, or explosion. Helping amateurs and others with their specialized problems, through professional knowledge and experience. Community service in organizing mobile and fixed communications to promote the success of fund drives and other public events. Helping disabled or physically handi- capped persons.
Relaying messages from remote points for the benefit of isolated servicemen and civilians. Designing and constructing rodio equipment for use by persons in remote parts of the world, who do not have accefs to regular commercial communication channels. Civil -defense organization. work; weather reporting; radio assistance to state or local traffic and police authorities; cooperation in forest -fire prevention and control. Teaching basic electronics to young people.
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NOTE: The disclosure of any information or ar- rangements herein conveys no license under any patents of General Electric Company or others. In the absence of an express written agreement to the contrary, the General Electric Company assumes no liability for patent Infringement (or any other liabil- ity) arising from the use of such Information by others.
HAM
MEWS G
presents HOW -TO -DO -IT IDEAS from the 999 radio amateurs at
GENERAL (A ELECTRIC A bi-monthly publication of the RECEIVING TUBE DEPARTMENT Owensboro, Kentucky, U. S. A. Editor - E. A. Neal, W4ITC
NOVEMBER -DECEMBER 1961
VOL. 1 6, NO. 6
RADIO PRODUCTS
)IE(URN POSTAGE GUARANTEED
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RULES OF THE AWARD
WHO IS ELIGIBLE? Any man or woman hold- ing a radio amateur's license issued by the F.C.C., Washington, D.C., who in 1961 per- formed a meritorious public service in be- half of an individual or group. The service must have been performed while the candi- date was pursuing his hobby as an amateur within the limits of the United States. RECIPIENT OF THE AWARD will receive the Edison trophy in a public ceremony in Washington, D.C. Expenses of his trip to that city will be paid.
$500 GIFT. Recipient will be presented with a check for this amount in recognition of the public service which he has rendered as a radio amateur. WHO CAN NOMINATE? Any individual, club; or association familiar with the public serv- ice performed. HOW TO NOMINATE. Include in a letter a full description of the service performed, as well as the candidate's name, address, and call letters. Your letter of nomination must be postmarked not later than January 3, 1962.
BASIS FOR JUDGING: All entries will be re- viewed by a group of distinguished and im- partial judges. Their decisions will be based on (1) the greatest benefit to an individual or group, (2) the amount of ingenuity and sacrifice displayed in performing the service. EDISON AWARD JUDGES WILL BE: E. ROLAND HARRIMAN, Chairman, The American National Red Cross. ROSEL H. HYDE, Commissioner, Federal Communications Committee. GOODWIN L. DOSLAND, President, Ameri- can Radio Relay League. Recipient of the Award will be announced on or before Thomas A. Edison's birthday, February 11, 1962.
Employees of the General Electric Com- pany may nominate candidates for the Edi- son Radio Amateur Award, but are not per- mitted to receive the Award.
Season's Greetings to All!
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