Difference between revisions of "Modifying Kenwood TK-760(H)/762(H)/860(H)/862(H) for Packet Service"
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[[File:TK-n6n_ribbon_COR_selector_feedback2.jpg|320px]] | [[File:TK-n6n_ribbon_COR_selector_feedback2.jpg|320px]] | ||
+ | |||
+ | 84) Pull the COR wire through the heatshrink, making it about even in length with the previously assembled TX audio selector jumper | ||
+ | |||
+ | [[File:TK_n6n_ribbon_COR_selector_feedback3.jpg|320px]] | ||
+ | |||
+ | 85) Take a 2.54mm header pin and tin 3 consecutive pins. | ||
+ | |||
+ | [[File:TK-n6n_TX_input_3pin_header_tin.jpg|320px]] | ||
+ | |||
+ | 86) Cut the 2.54mm 3 pin header which has it's pins tinned. | ||
+ | |||
+ | [[File:TK-n6n_TX_input_3pin_header_cut.jpg|320px]] | ||
+ | |||
+ | 87) Cut 2 pieces about 3/8" long of 1/8" heatshrink tubing | ||
+ | |||
+ | [[File:TK-n6n_COR_heatshrink_cut.jpg|320px]] | ||
+ | |||
+ | 88) Take about 3" of single wire from the ribbon cable, strip about 1/8" and tin the end to be used for the COR enable switch . In this build this wire is orange. | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_output_cut.jpg|320px]] | ||
+ | |||
+ | 89) Solder the COR enable output wire to the center pin of the 3 pin header | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_output_connected.jpg|320px]] | ||
+ | |||
+ | 90) Slide one of the 3/8" long 1/8" heatshrink tubing sections over the COR input wire | ||
+ | |||
+ | [[File:TK-n6n_COR_output_heatshrink_over.jpg|320px]] | ||
+ | |||
+ | 91) Solder the COR input wire to an outside pin of the 3 pin header, moving up the heatshrink over the soldered point. Also slide the other piece of heatshrink tubing over the output in and the unused pin on the 3 pin header. | ||
+ | |||
+ | [[File:TK-n6n_COR_input_connected_heatshrink_in_place.jpg|320px]] | ||
+ | |||
+ | 92) Fold the COR enabling header, wires and heatshrink over the bottom cover of the radio to provide a heat shield | ||
+ | |||
+ | [File:TK-n6n_COR_input_over_bottom_cover.jpg|320px]] | ||
+ | |||
+ | 93) Apply heat to heatshrink, ensuring the center wire heatshrink closes around the outer, unused pin | ||
+ | |||
+ | [[File:TK-n6n_COR_input_heatshrink_applied.jpg|320px]] | ||
+ | |||
+ | 94) Take a 2.54mm jumper and slide it over 2 of the pins on the COR output enable jumper. | ||
+ | |||
+ | In this position, the COR output will be passed | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_enabled.jpg|320px]] | ||
+ | |||
+ | In this position, the COR output will not be passed | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_disabled.jpg|320px]] | ||
+ | |||
+ | 95) Slide the COR selctor output wire back through the 1/4" heatshrink tubing | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_output_wire_through_heatshrink1.jpg|320px]] | ||
+ | [[File:TK-n6n_COR_selector_output_wire_through_heatshrink2.jpg|320px]] | ||
+ | [[File:TK-n6n_COR_selector_output_wire_through_heatshrink3.jpg|320px]] | ||
+ | |||
+ | 96) Cut the COR selector output wire to length to mate up with the Devicenet white wire | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_output_wire_cut_to_length.jpg|320px]] | ||
+ | |||
+ | 97) Strip back about 3/16" and tin the COR selector output wire. | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_output_stripped_tinned.jpg|320px]] | ||
+ | |||
+ | 98) Slide about 3/8" of the 1/8" heatshrink tubing over the COR selector output wire. | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_output_with_heatshrink.jpg|320px]] | ||
+ | |||
+ | 99) Solder the COR selector output wire to the white Devicenet wire | ||
+ | |||
+ | [[File:TK-n6n_COR_selector_output_connected.jpg|320px]] | ||
+ | |||
+ | 100) Slide all 5 sections of heatshrink over the soldered junctions between the ribbon cable and Devicenet cable | ||
+ | |||
+ | [[File:TK-n6n_ribbon_to_devicenet_heathsrink.jpg|320px]] | ||
+ | |||
+ | 101) Place the bottom cover of the radio over the ribbon cable to provide a heatshield, only exposing the 5 sections that were put in place in the previosu step | ||
+ | |||
+ | [[File:TK-n6n_ribbon_to_devicenet_heathshrink_bottom_cover_heatshield.jpg|320px]] | ||
+ | |||
+ | 102) Apply heat to the heatshrink using a heat gun, hair dryer or similar method | ||
+ | |||
+ | [[File:TK-n6n_ribbon_to_devicenet_heatshrink_applied.jpg|320px]] | ||
+ | |||
+ | 103) Slide the 1/4" heatshrink tubing over the 5 sections that were just applied | ||
+ | |||
+ | [[File:TK-n6n_ribbon_to_devicenet_1_4in_slide1.jpg|320px]] | ||
+ | [[File:TK-n6n_ribbon_to_devicenet_1_4in_slide2.jpg|320px]] | ||
+ | [[File:TK-n6n_ribbon_to_devicenet_1_4in_slide3.jpg|320px]] | ||
+ | |||
+ | 104) Apply heat to the heatshrink using a heat gun, hair dryer or similar method | ||
+ | |||
+ | [[File:TK-n6n_ribbon_to_devicenet_outer_heatshrink_applied.jpg|320px]] | ||
+ | |||
+ | 105) Wrap electrical tape around the outer heatshrink layer, ensuring that all the folded back braid from the Devicenet cable is also covered | ||
+ | |||
+ | [[File:TK-n6n_ribbon_to_devicenet_taped.jpg|320px]] | ||
+ | |||
+ | 106) Review the jumper selection for the TX audio input, as shown will send TX audio to the Microphone input. Slide the 1/4" heatshrink overtop to provide insulation | ||
+ | |||
+ | [[File:TK-n6n_TX_audio_selector_review.jpg|320px]] | ||
+ | [[File:TK-n6n_TX_audio_selector_covered.jpg|320px]] | ||
+ | |||
+ | 107) Review the jumper for COR output, as shown COR output will not be sent. Slide the 1/4" heatshrink over top to provide insulation | ||
+ | |||
+ | [[File:TK-n6n_COR_output_review.jpg|320px]] | ||
+ | [[File:TK-n6n_COR_output_covered.jpg|320px]] | ||
+ | |||
+ | 108) Locate the speaker and reinsert the connector onto the main board | ||
+ | |||
+ | [[File:TK-n6n_speaker_reconnect1.jpg|320px]] | ||
+ | [[File:TK-n6n_speaker_reconnect2.jpg|320px]] | ||
+ | [[File:TK-n6n_speaker_reconnect3.jpg|320px]] | ||
+ | |||
+ | 109) Take the speaker and plastic speaker mount and reattach it to the chassis | ||
+ | |||
+ | [[File:TK-n6n_speaker_mount_reinstalled.jpg|320px]] | ||
+ | |||
+ | 110) Lift the power cable out of the groove in the rear of the chassis, next to the heatsink fins | ||
+ | |||
+ | [[File:TK-n6n_power_cable_removed.jpg|320px]] | ||
+ | |||
+ | 111) Insert the Devicenet cable in the groove previously occupied by the power cable | ||
+ | |||
+ | [[File:TK_n6n_devicenet_in_grove1.jpg|320px]] | ||
+ | [[File:TK_n6n_devicenet_in_grove2.jpg|320px]] | ||
+ | |||
+ | 112) Reinsert the power cable into the original groove, it will not sit flush with the chassis at this point | ||
+ | |||
+ | [[File:TK-n6n_power_cable_reinstalled.jpg|320px]] | ||
+ | |||
+ | 113) Take the top cover with the holes for the speaker and place it back on the top of the radio. The screw opposite of the Devicenet and power cable and the two front screws can be tightened normally. | ||
+ | |||
+ | [[File:TK-n6n_top_cover_installed_3_screws.jpg|320px]] | ||
+ | |||
+ | 114) The screw in the corner with the Devicenet and power cable should be able to begin to thread, but do not try and tighten it fully. | ||
+ | |||
+ | [[File:TK-n6n_top_cover_4th_screw_started.jpg|320px]] | ||
+ | |||
+ | Note the gap in the side of the cover next to the Devicenet and power cables | ||
+ | |||
+ | [[File:TK-n6n_top_cover_gap.jpg|320px]] | ||
+ | |||
+ | 115) Flip the radio over and install the bottom cover, all 4 screws can be tightened normally | ||
+ | |||
+ | [[File:TK_n6n_bottom_cover_installed.jpg|320px]] | ||
+ | |||
+ | 116) Flipping the radio back over, place the radio under a flat and heavy surface (workbench works well) and push upwards, this will cause the devicenet cable to push downward and the rubber grommet of the power cable to spread out. This will make the case flush with the radio and the screw head should appear raised. | ||
+ | |||
+ | [[File:TK-n6n_top_pressed.jpg|302px]] | ||
+ | |||
+ | 117) Finish tightening the top case screw near the power and Devicenet cable. | ||
+ | |||
+ | [[File:TK-n6n_top_secured.jpg|320px]] | ||
+ | |||
+ | 118) Check the side of the case to ensure it's made a firm seal with no major gaps between top and bottom covers. | ||
+ | |||
+ | [[File:TK-n6n_top_cover_check.jpg|320px]] | ||
+ | |||
+ | 119) | ||
+ | |||
+ | |||
Revision as of 22:41, 27 June 2021
The Kenwood TK-760(H)/762(H)/860(H)/862(H) are relatively low cost commercial radios that can be reprogrammed to work in the 2m and 70cm bands and depending on band and model are rated for 25-45w output. With a steady hand and fine tipped soldering iron, they can be modified for 1200-9600 baud service, VARA FM/FM Wide, including optional COR/COS signaling for hardware carrier detect or use in other services like Allstarlink, Echolink, SVXLink, Repeater controllers/remote base, etc. This guide wires them to the Kantronics DB-9 standard and is compatible with the 4 Port packet controller and NinoTNC, details to support adaptation to other interfaces/TNCs/controllers is included.
Model | Band | Channel Capacity | Output Power | Subband Splits |
TK-760 | VHF High (2m) | 32 | 25W | 1 = 148-174 MHz, 2 = 136-156 MHz |
TK-760H | VHF High (2m) | 32 | 45W | 1 = 148-174 MHz, 2 = 136-156 MHz |
TK-762 | VHF High (2m) | 2 | 25W | 1 = 148-174 MHz, 2 = 136-156 MHz |
TK-762H | VHF High (2m) | 2 | 45W | 1 = 148-174 MHz, 2 = 136-156 MHz |
TK-860 | UHF (70cm) | 32 | 25W | 1 = 450-476 MHz, 2 = 470-496 MHz, 3 = 488-512 MHz, 4 = 406-430 MHz |
TK-860H | UHF (70cm) | 32 | 35W | 1 = 450-476 MHz, 2 = 470-496 MHz, 3 = 488-512 MHz, 4 = 406-430 MHz |
TK-862 | UHF (70cm) | 2 | 25W | 1 = 450-476 MHz, 2 = 470-496 MHz, 3 = 488-512 MHz, 4 = 406-430 MHz |
TK-862H | UHF (70cm) | 2 | 35W | 1 = 450-476 MHz, 2 = 470-496 MHz, 3 = 488-512 MHz, 4 = 406-430 MHz |
A note on Bandsplits
The band splits are indicated differently between some documentation and what is actually printed on the radio. The labels on the radio seem to be numeric while the documentation references the letter K. Cross referencing the two:
K, HK = 1
K2, HK2 = 2
K3, HK3 = 3
K4, HK4 = 4
For VHF, the K(1) is the most common split, but both the K(1) and K2 splits cover all of 2m (144-148 MHz) without issue. For UHF, the K(1) split is also the most common split (450-470 MHz) and can usually cover at least 438-450 MHz, some of them will go down as low as 430 MHz with a simple VCO adjustment. The less common K2 (470-496 MHz) and K3 (488-512 MHz) splits are too far away from the 70cm band to be used and should be avoided except for part donors. The least common K4 split (406-430 MHz) can probably cover the lower portions of the 70cm band, possibly up to 440 or higher. We have not been able to obtain any of these to test, though they be may more available in proximity to Line A along the northern border of the USA and up in Canada where it is a commercial band. If you do end up with a K4 split and want a K split, please contact us to arrange a trade, we will cover shipping in both directions.
Required parts
1) Around 12" of 6 or more conductor ribbon cable, multicolor suggested
2) 34" of Devicenet 2 pair 22 gauge cable
3) 1-2x 3 pin 2.54mm header, commonly available for Raspberry Pi and Arduino projects (Optional 1 for COR logic signaling enable/disable and/or changing TX audio between mic and modulator input)
4) 1-2x 2.54mm jumper (Optional for connections on item 3)
5) 1/8" heatshrink tubing
6) 1/4" heatshrink tubing
7) DB9 male, solder cup type suggested
8) DB9 hood, metal plated suggested
9) Electrical tape
10) Fine tipped soldering iron and solder
11) #1 or #2 Phillips screwdriver
12) Edge wire cutters
13) Box cutter or similar knife
14) Wire stripper for 22awg wire (optional)
15) Multimeter for testing (optional)
Modification Process
Prior to beginning any modification, it is best to test the radio for proper functionality. If the radio was purchased used, there is a fair chance it is programmed to commercial frequencies. Reprogramming into the amateur bands is possible for the TK-760(H)G/762(H)G/860(H)G/862(H)G using the KPG-29D software which is available for DOS only. In general, the VHF high band versions will work well into the 2m band with little or no adjustments needed to the VCO or receiver. The UHF versions (K split, 450-470 MHz) will often work without modification in the upper 10 MHz (440-450 MHz) and sometimes lower. Many of the UHF versions can go lower into the 70cm band by adjusting the VCO circuits. Some may go down as low as 430 MHz or possibly lower. It should be possible to add small amounts of parallel capacitance across the trimmer capacitors in the VCO section to pull it's range lower in frequency. This will likely be explored in the future.
1) Open the top cover by removing the four screws near the heatsink and face of the radio
2) Lift the speaker and plastic speaker mount off the chassis and set both off to the side.
3) Use a pair of pliers to gently pull out the speaker from the main board, setting the speaker aside for now.
4) Flipping the radio over, remove the bottom cover by removing the four screws near the heatsink and face of radio
6) Flipping the radio back over, gently lift up on the plastic tabs and push the faceplate forward.
5) Flipping the radio over again, gently lift the plastic tabs attached to the faceplate and slide the faceplate forward.
7) Pull the faceplate away from the chassis to expose the faceplate circuit board
8) Gently apply pressure to the brown tabs holding the flat ribbon cable to the back of the faceplate circuit board
93) Apply heat to heatshrink, ensuring the center wire heatshrink closes around the outer, unused pin
94) Take a 2.54mm jumper and slide it over 2 of the pins on the COR output enable jumper.
In this position, the COR output will be passed
In this position, the COR output will not be passed
95) Slide the COR selctor output wire back through the 1/4" heatshrink tubing
96) Cut the COR selector output wire to length to mate up with the Devicenet white wire
97) Strip back about 3/16" and tin the COR selector output wire.
98) Slide about 3/8" of the 1/8" heatshrink tubing over the COR selector output wire.
99) Solder the COR selector output wire to the white Devicenet wire
100) Slide all 5 sections of heatshrink over the soldered junctions between the ribbon cable and Devicenet cable
101) Place the bottom cover of the radio over the ribbon cable to provide a heatshield, only exposing the 5 sections that were put in place in the previosu step
102) Apply heat to the heatshrink using a heat gun, hair dryer or similar method
103) Slide the 1/4" heatshrink tubing over the 5 sections that were just applied
104) Apply heat to the heatshrink using a heat gun, hair dryer or similar method
105) Wrap electrical tape around the outer heatshrink layer, ensuring that all the folded back braid from the Devicenet cable is also covered
106) Review the jumper selection for the TX audio input, as shown will send TX audio to the Microphone input. Slide the 1/4" heatshrink overtop to provide insulation
107) Review the jumper for COR output, as shown COR output will not be sent. Slide the 1/4" heatshrink over top to provide insulation
108) Locate the speaker and reinsert the connector onto the main board
109) Take the speaker and plastic speaker mount and reattach it to the chassis
110) Lift the power cable out of the groove in the rear of the chassis, next to the heatsink fins
111) Insert the Devicenet cable in the groove previously occupied by the power cable
112) Reinsert the power cable into the original groove, it will not sit flush with the chassis at this point
113) Take the top cover with the holes for the speaker and place it back on the top of the radio. The screw opposite of the Devicenet and power cable and the two front screws can be tightened normally.
114) The screw in the corner with the Devicenet and power cable should be able to begin to thread, but do not try and tighten it fully.
Note the gap in the side of the cover next to the Devicenet and power cables
115) Flip the radio over and install the bottom cover, all 4 screws can be tightened normally
116) Flipping the radio back over, place the radio under a flat and heavy surface (workbench works well) and push upwards, this will cause the devicenet cable to push downward and the rubber grommet of the power cable to spread out. This will make the case flush with the radio and the screw head should appear raised.
117) Finish tightening the top case screw near the power and Devicenet cable.
118) Check the side of the case to ensure it's made a firm seal with no major gaps between top and bottom covers.
119)
Post modification testing
Multimeter + Second radio testing:
1) Take a continuity tester and verify a DC short between the DB9 pin number 6 and the radio chassis as well as DB9 shell
2) Measure for DC voltage across DB9 pin number 3 (PTT). If present, attach suitable antenna or dummy load to modified and short pin 3 to the DB9 shell or DB9 pin 6, this should cause the radio to transmit.
3) Measure AC voltage across DB9 pin 5. This is discriminator receive audio and will be a fairly steady AC voltage with no signal present. If AC voltage is measured and another transmitter is available, transmit a dead carrier with no audio, this should cause the AC voltage to drop significantly if not fully near 0 volts indicating the receiver has a full quieting signal.
4) If the COR circuit was added and COR enable jumper was placed, measure DC voltage across DB9 pin number 2. With no signal present, the DC voltage should be near 0. Using either the MON function on the front of the radio OR using a secondary transmitter on the frequency, open up the squelch and this pin should read about 5VDC.
5) Create a short between DB9 pin numbers 1 (TX Audio) and 5 (RX Audio). On an secondary receiver, tune to the modified radio transmit frequency. Short DB9 pin 3 to ground either on the DB9 shell or DB9 pin 6. This should cause the radio to transmit and the secondary receiver should pick up a signal with static. Momentarily break the short between DB9 pin numbers 1 and 5, this should turn the signal from full quieting and static off the discriminator.
Soundcard interface/packet controller/hardware TNC testing:
1) Attach the radio to a compatible interface. If the interface/TNC does not use the Kantronics DB9 standard, a suitable adapter will need to be made. To review, the DB9 pinout is:
DB9 Pin 1 = TX Audio
DB9 Pin 2 = COR (Active High) - if built and enabled
DB9 Pin 3 = PTT (Active Low)
DB9 Pin 5 = RX Audio
DB9 Pin 6 = Ground
2) Place the modified radio on a known packet frequency. If none is available on VHF, a good candidate for traffic is the national APRS frequency, 144.390 MHz in North America, 144.80 in Europe. Optionally turn up the volume on the radio and listen for packet bursts to come out of the speaker. When a packet burst is heard, check the interface/TNC for a successful decode.
3) Placing an auxiliary receiver on the radio transmit frequency, issue an outbound connection and listen for a packet burst on the auxiliary receiver. If no other station exists, a dummy call can be used:
C XX1XX
Please contact us any modification questions or suggestions regarding this modification process.