Difference between revisions of "SSB6 Design"
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− | [[FILE: | + | [[FILE:SSB6_P1916-720px.jpg]] |
== Design == | == Design == | ||
Line 5: | Line 5: | ||
* 6 element filter | * 6 element filter | ||
* [http://w7zoi.net/filters/9megxfils.pdf W7ZOI Crystal Filter paper] has several crystal filter designs | * [http://w7zoi.net/filters/9megxfils.pdf W7ZOI Crystal Filter paper] has several crystal filter designs | ||
− | * Narrow bandwidth bandpass filters for SSB | + | ** Narrow bandwidth bandpass filters for CW/SSB |
+ | ** This is the 6 crystal SSB6 | ||
* Used for transmit/receive | * Used for transmit/receive | ||
* 9 MHz nominal frequency | * 9 MHz nominal frequency | ||
Line 48: | Line 49: | ||
[[file:Dishal-sim-01.PNG]] | [[file:Dishal-sim-01.PNG]] | ||
− | |||
− | |||
− | |||
− | |||
=== Measured Crystal Values === | === Measured Crystal Values === | ||
Line 84: | Line 81: | ||
* NanoVNA | * NanoVNA | ||
* 2.5 KHz / div | * 2.5 KHz / div | ||
+ | * Initial measurement shows issues (solved later on this page) | ||
[[file:SSB6_NanoVNA_9MHz_2.5KHzPerDiv.png]] | [[file:SSB6_NanoVNA_9MHz_2.5KHzPerDiv.png]] | ||
Line 119: | Line 117: | ||
=== Improvements === | === Improvements === | ||
− | ==== | + | * Investigate changes to remove ripple and clean up right side of passband |
+ | |||
+ | ==== Clean Board ==== | ||
* Cleaned board | * Cleaned board | ||
* Removed wires on transformer that were not clipped flush-ish | * Removed wires on transformer that were not clipped flush-ish | ||
− | * No effect - same ripple, same drop at the right side, same insertion loss | + | ** No effect - same ripple, same drop at the right side, same insertion loss |
+ | * No change | ||
+ | |||
+ | [[file:SB6_NanoVNA_9MHz_1KHzPerDiv_Added_Grounds.png]] | ||
+ | |||
+ | ==== Add grounds to cases of crystals ==== | ||
+ | |||
+ | * Had to scrape away solder mask to solder | ||
+ | ** Through hole vias were plated through | ||
+ | ** Would be better with ground pads with cleared solder mask and thermal relief (Version 2) | ||
+ | * No change | ||
+ | |||
+ | [[file:SSB6_P1889_Soldered-Grounded_Cases_720PX.jpg]] | ||
==== Incremental Build and Test ==== | ==== Incremental Build and Test ==== | ||
* Start with unpopulated board | * Start with unpopulated board | ||
− | + | * Add SMA connectors | |
− | * | + | |
+ | [[file:SSB6_P1887_Test_01_SMAs-Installed_720PX.jpg]] | ||
+ | |||
+ | * Added transformers | ||
+ | * Installed 200 ohm resistors at input caps to ground | ||
+ | ** At C1, C11 | ||
+ | |||
+ | [[file:SSB6_P1891_tEST_02_TRANSFORMER_TEST.JPG]] | ||
+ | |||
* Measure transformer impedances from NanoVNA | * Measure transformer impedances from NanoVNA | ||
** Input | ** Input | ||
Line 137: | Line 157: | ||
*** 48.7-j0.714 Ohms | *** 48.7-j0.714 Ohms | ||
*** VSWR 1:1.031 | *** VSWR 1:1.031 | ||
− | * | + | * Impedance is flat over passband |
+ | * Transformer working as expected | ||
[[file:SSB6_NanoVNA_9MHz_Transformer_Input_Impedance.png]] | [[file:SSB6_NanoVNA_9MHz_Transformer_Input_Impedance.png]] | ||
* 1-30 MHz scan | * 1-30 MHz scan | ||
− | * Toroid | + | * Toroid flat to board or tilted up = same performance |
+ | * Not flat over band, but OK at 9 MHz | ||
[[file:SSB6_NanoVNA_1-30MHz_Transformer_Input_Impedancee.png]] | [[file:SSB6_NanoVNA_1-30MHz_Transformer_Input_Impedancee.png]] | ||
+ | |||
+ | * Add machine socket pins to install parts | ||
+ | |||
+ | [[FILE:SSB6_P1892-720px.jpg]] | ||
+ | |||
+ | * Install caps in socket pins | ||
+ | |||
+ | <pre> | ||
+ | 08 8.997809 10.3 10.3 | ||
+ | 30 8.997810 11.3 11.3 | ||
+ | 48 8.997812 13.3 13.3 | ||
+ | 50 8.997814 15.3 15.3 | ||
+ | 31 8.997818 19.3 19.3 | ||
+ | 46 8.997822 23.3 23.3 | ||
+ | </pre> | ||
+ | |||
+ | * Parts installed on pinned card | ||
+ | |||
+ | [[file:PinJig-01.png]] | ||
+ | |||
+ | ==== Fixed First Card ==== | ||
+ | |||
+ | * Compared pinned board to first board | ||
+ | * Noted C5 and C6 were swapped | ||
+ | * Repaired | ||
+ | * Sweep | ||
+ | |||
+ | [[file:PinJig-02.png]] | ||
+ | |||
+ | * Excellent results | ||
+ | * 2.625KHz bandwidth - close to 2.5KHz design goal | ||
+ | * 2.5 dB insertion loss | ||
+ | * Low ripple. | ||
+ | * Fcenter = 8.998892 MHz | ||
+ | |||
+ | [[file:PinJig-03.png]] | ||
+ | |||
+ | ==== SSB4 vs SSB6 ==== | ||
+ | |||
+ | [[file:SSB4_vsS_SB6_NanoVNA_9MHz_1KHzPerDiv-fixed.png]] | ||
+ | |||
+ | * Input complex impedance across passband | ||
+ | |||
+ | [[ile:SSB6_Input Impedance_InPassband.png]] | ||
== References == | == References == |
Latest revision as of 10:59, 30 October 2021
Contents
Design
- 6 element filter
- W7ZOI Crystal Filter paper has several crystal filter designs
- Narrow bandwidth bandpass filters for CW/SSB
- This is the 6 crystal SSB6
- Used for transmit/receive
- 9 MHz nominal frequency
- 50 Ohms in/out impedance
- Bin crystals using Colpitts Crystal Oscillator
- Hand select close values from a pile of crystals
- Can get much closer than 10% of bandwidth with 50 crystals
- W7ZOI Filters on Kits and Parts Boards
- Other filter builds
- 5 or less crystals
W7ZOI SSB6 Schematic
- Response curve
Build
- SSB6 filter is too big for Kits and Parts board (5 crystals limit)
- 2500 Hz bandwidth
Schematic
Dishal Values
- Impedance = 195.9
RefDes Dishal RefDes W7ZOI Ck12 87.3 C3/C9 82 Ck23 110.9 C4/C8 100 Ck34 114.4 C6 100 Cs1 110 C2/C10 120 Cs3 369.5 C5/C7 470
Measured Crystal Values
- 6 crystals within 7 Hz of each other
- Selected from 50 purchased
Number Freq Delta from average 09 8.997791 -7.7 12 8.997791 -7.7 41 8.997793 -5.7 06 8.997794 -4.7 21 8.997798 -0.7 38 8.997798 -0.7
Enclosure 80x50x20
- Fits in 80x50 extruded enclosure
- Material: Aluminum
- Color: black
- Size: approx.80*50*20mm
- Thickness: approx.1mm
Performance Measurements
Overall
- NanoVNA
- 2.5 KHz / div
- Initial measurement shows issues (solved later on this page)
Detailed
- 1 KHz/div
- Bandpass looks about 2500 KHz = good
- Left freq = 8.99762 MHz
- Right freq = 9.00005 MHz
- Delta = 2.43 KHz
- Center frequency = 8.99885 MHz
- Implies crystals are properly matched?
- Insertion loss at "best" point (red marker) -5.14 dB = OK
- Deep skirts = good
- Ripple looks bad
- Right side low
Compared to SSB4
- Fcenter = 8.998MHz
- Span = 10KHz
- 1 KHz/div
- Skirts much deeper on SSB6 than SSB4
- -90 dB on SSB6 at window edges
- -60 dB on SSB4 at window edges
- Passband much flatter on SSB4
- Insertion loss lower on SSB4
- SSB4
Improvements
- Investigate changes to remove ripple and clean up right side of passband
Clean Board
- Cleaned board
- Removed wires on transformer that were not clipped flush-ish
- No effect - same ripple, same drop at the right side, same insertion loss
- No change
Add grounds to cases of crystals
- Had to scrape away solder mask to solder
- Through hole vias were plated through
- Would be better with ground pads with cleared solder mask and thermal relief (Version 2)
- No change
Incremental Build and Test
- Start with unpopulated board
- Add SMA connectors
- Added transformers
- Installed 200 ohm resistors at input caps to ground
- At C1, C11
- Measure transformer impedances from NanoVNA
- Input
- 48.9-j0.900 Ohms
- VSWR 1:1.031
- Output
- 48.7-j0.714 Ohms
- VSWR 1:1.031
- Input
- Impedance is flat over passband
- Transformer working as expected
- 1-30 MHz scan
- Toroid flat to board or tilted up = same performance
- Not flat over band, but OK at 9 MHz
- Add machine socket pins to install parts
- Install caps in socket pins
08 8.997809 10.3 10.3 30 8.997810 11.3 11.3 48 8.997812 13.3 13.3 50 8.997814 15.3 15.3 31 8.997818 19.3 19.3 46 8.997822 23.3 23.3
- Parts installed on pinned card
Fixed First Card
- Compared pinned board to first board
- Noted C5 and C6 were swapped
- Repaired
- Sweep
- Excellent results
- 2.625KHz bandwidth - close to 2.5KHz design goal
- 2.5 dB insertion loss
- Low ripple.
- Fcenter = 8.998892 MHz
SSB4 vs SSB6
- Input complex impedance across passband
ile:SSB6_Input Impedance_InPassband.png
References
- Crystal ladder filters – Software
- Crystal Ladder Filters for All - ARRL QEX
- DISHAL software by DJ6EV
- A Practical Test Set for Comprehensive Crystal Testing
- Crystal characterization and crystal filter design
- Crystal parameters Written by Hans Summers (QRP Labs)