A complete HPSDR transceiver

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An example of a complete HPSDR transceiver using the Mercury, Penelope, and Ozy boards and other available hardware and software. It concludes with test measurements that compare the finished transceiver to other commercially available high end transceivers.

The goal is to build and operate the highest performance amateur radio transceiver that can be assembled using components documented on this wiki. Specifically in one case/enclosure, the following is expected:

A totally integrated transceiver with an integrated computer, audio amplifier, speaker, HPSDR components, and 10 to 50 watts of power output. Not included would be the keyboard, mouse, flat panel screen, and antenna tuner. You could compare the proposed rig to commercial rigs such as the Flex 3000, TS-B2000, FT-2000, FT-950, or Ten Tec Pegasus. The transceiver must be mechanically and electrically secure so that one would not hesitate to take one to a field day exercise or a DXpedition as a primary rig.

By Ron Cox, W9KFB (with help from the HPSDR group who made all this possible)

Enclosure

Rear view of case prepared for installation of HPSDR components

It may be possible to build the rig in the HPSDR's Pandora's box. It is very possible to do so if you are using a laptop computer and can keep the RF power out requirements to that needed for narrow band modes such as PSK31 and CW. That rig is being built, but two other rigs that were built came closer to meeting the specifications above. Using this experience, the specification goals will be met.

The following information on the Antec New Solutions Case was taken from their web site at [1]. In looking for a good case to build a transceiver that meets the specifications above and that allows you to access and modify the circuitry without getting in the way, we found that this case meets most of the requirements and delivers many unexpected bonus features. The specific Antec case is a model NSK2480 in the "New Solutions Series". Here are the main selling points about this case and power supply that sells for under $100 USD at most internet suppliers that carry Antec cases:

Power Supply

  • The power supply is acoustically quiet and highly efficient.
    The 80 PLUS® Certified EarthWatts 380W power supply
  • The 80 PLUS® Certified EarthWatts 380W power supply is also very quiet electrically and has no detectable switching power supply signals. If any spurious signals are detected in testing, we will eliminate them using clamp-on ferrites.
  • Universal input (100 - 240 volts at 6 Amps with 50 or 60Hz). This power supply must power all the HPSDR components that we put in this case.

Case Structure

View of case after installation of Intel D945GCLF2D board
  • 0.8 mm cold-rolled steel construction
  • Triple-chamber structure to isolate power supply and amplifier heat for cooler & quieter operation
  • 2 Drive Bays are used for HPSDR components, no optical drives will be mounted here
  • 2 Hard Drive bays are available for Hard Drives
  • 4 Expansion Slots - Only one will be usable as an expansion slot because we will use a Mini-ITX motherboard
  • Front-mounted ports for easy mike and earphone connections: 2 x USB 2.0 (example: Griffin Knob and/or USB DSP headset); Audio in and out (analog mike and headset)
  • Unit Dimensions: 5.5" (H) x 17.5" (W) x 16.3" (D); 13.97cm (H) x 44.5cm (W) x 41.4cm (D)

The height of the enclosure makes it possible to mount the HPSDR Atlas, Mercury, Ozy and Penelope boards.

Cooling Design

  • Advanced cooling system: 2 side mounted 120 mm TriCool™ 3-speed fans

The fans really only cool one of the three chambers, the one with the computer mounted in it, but they are very low noise when set at low or medium speeds.

Motherboard and CPU

Sony DRX840U 20x External Dual-Layer DVD Burner

From experience building several HPSDR transceivers in this case, we have found that all is needed is a small footprint Mini IPX motherboard. No extra I/O cards are required if one uses virtual software ports. By using SATA drive ports exclusively we can use such a small motherboard. An Intel DQ45EK Desktop Board was ordered for this project, but a better lower cost solution is to use the new Intel D945GCLF2D board with a Dual-Core Intel Atom Processor and Integrated Graphics. A test of running PowerSDR on this processor resulted a CPU usage of less than 30%!

Memory Module

The Intel D945GCLF2D Motherboard will only work with up to 2 GB of 667MHz single module speed memory. The cost was $28.99 USD with a $10 USD mail-in rebate.

Disk Drive(s)

The motherboard will service two serial SATA ports (3.0 GB/s) and one parallel ATA IDE interface with UDMA 33, ATA-66/100 support. The most cost effective drive available should be used. Currently the Hitachi Deskstar P7K500 500GB Hard Drive - 7200, 16MB, SATA-300, OEM for $54.97USD looks to be a good deal for low cost hard drives.

(Optional) External Optical Drive

Rear view of case after installation of iCube speaker
Inside view of case after installation of iCube speaker
Inside view of case after installation of the current HPSDR Components

This facility is used to load programs but there is not enough room in the case for the drive. It is seldom used and a thumb drive is a good substitute for just copying and transferring programs from one computer to another. Sony makes a nice matching portable drive that several hams are using with this HPSDR transceiver as needed via a USB2 cable. The Sony model number is DRX-840U (see photo). Cost is $99.99.

OEM Operating System

The only way to buy an operating system for a new system like this is to purchase the OEM version. Most internet stores should carry it. To be compatible with most of the popular HPSDR software, Windows XP home edition works. Amazon.com lists " Microsoft Windows XP Home Edition SP2B for System Builders [OLD VERSION] by Microsoft Software (CD-ROM) (Windows XP) Buy new: $86.91 2 Used & new from $86.91"

HPSDR Components

Part Name Price ($US)
Atlas Kit- TAPR 35.00
Mercury RX - TAPR 329.00
Penelope TX - NT-Electronics 357.54
Ozymandias-mini - NT-Electronics 214.79 (Preliminary)
Antenna Switch - NT-Electronics Only used if Alex is not available 73.99
Alexiares - TAPR TBD
PennyWhistle - TAPR TBD
100 Watt 160 M to 6 M Amplifier - TBD TBD

Audio Amplifier & Speaker

The issue of how to best add an audio amplifier & speaker to a computer/HPSDR rig has been unresolved for some time. We now have a good solution. Normally the Mercury board's line out will be connected directly to the computer's line input. If one wanted amplification, for example in a noisy environment, then an audio power amplifier with appropriate power level would be used. Per the specifications the HPSDR transceiver we are designing and building must have an internal speaker component. A good small speaker with a battery powered amplifier was purchased at Fry's Electronics. It is called the iCube distributed by I_Concepts, and it cost $3.90 USD. The iCube was modified to run on 5 Volt computer power by putting a 5 volt computer style connector on it and using a 10 uf and .01 uf cap in parallel across the power input to the iCube to reduce the low level noise. The iCube was mounted to the cold rolled steel cabinet back with 4 sheet metal screws (see photo).

Layout of Components

It is not a complex project to layout the components for this transceiver. The motherboard and all her attachments are all located per the the instructions for the motherboard. The best place for the Atlas board is in the Optical Drives Bay. The Alex board set will attach on the wall where the USB2 cord is running to the rear. The decision on witch way to face the connectors is still being considered. If they face the rear, the mike and key jacks will be located on the end plate with the holes for the Alex BNCs. If the Alex boards BNCs face the front on the inside, most of the BNC wiring will be shorter and more direct and not be visible on the back any more.

Antenna Switch

Inside view of case after installation of the Antenna Switch

The Antenna Switch was the last HPSDR component to be installed. It was originally installed next to the power supply on the outside enclosure wall with two standoffs. The first tests of the completed transceiver had switching noise throughout the HF spectrum. It was found to be radiated noise being picked up in the Antenna Switch due to its physical non-conducting contact with the main bundle of wires coming out of the power supply. Relocating the Antenna Switch into the corner at the end of the Atlas board solved the problem.

Inside view of case after all wiring completed

Wiring

The completed wiring did not change any of the power supply or front panel connectors, so those two components could be replaced with no special wiring changes. The only custom wiring done in the enclosure was the atlas power connectors, a short jumper cable that consists of a 20 pin power supply connector wired to a four pin hard drive power connector, and the 12 volt power leads for the Antenna Switch soldered to the 12 volt eyelets on the Atlas board.

Key, Mike, and PTT Interface Assembly

Key, Mike, and PTT options interface

The Key, Mike and PTT interface jacks can all be located on one removable PC expansion filler plate per the photo. We wired it so that the Ozy all ways controlled PTT and made it so one could use the mike jack as a PTT mike or just a PTT switch, assuming that the the Mike audio was delivered via VAC. All non ground terminations on the panel were RF bypassed with a .01 uf capacitor.

Ozy DB9 Pin

5: Common/Gnd

6: Key Dash

7: Key Dot

8: PTT

Penelope Audio cable

Tip: Audio

Ring: Audio

Shield: Common/Ground

USB Microphone Option

An analog microphone jack is provided with a direct connection to the Penelope transmitter board, but the thought of using a USB mike instead via the Virtual Audio cable seemed like a better match for the high performance we expect from this HPSDR rig. A Logitech USB Desk Microphone was purchased for $29.99 and the VAC settings to operate it were established as:

Follow FlexRadio instructions: How to Setup Virtual Audio Cable (VAC) 4.0x with PowerSDR 1.x at [2]

  1. In PowerSDR Setup > Audio > VAC,
  2. Set Enable VAC
  3. Driver: Windows DirectSound
  4. Input: AK5370
  5. Output: Virtual Cable 2
  6. Stereo: Unchecked
  7. Enable for Digital Modes: Unchecked
  8. Allow PTT to override: Unchecked

In PowerSDR Mode USB, LSB, DSB, AM or FM, Turn on VAC for the USB mike and turn it off for the analog mike.

Result: Very excellent low noise, noise cancelling microphone input via USB.

BNC Cables

Complete W9KFB Transceiver Front view

In thinking ahead of what we are going to need for wiring this HPSDR transceiver, one set of items stand out as essential, BNC cables. First lets count the number of BNC connections in this rig:

1. Mercury 1

2. Penelope 1

3. Alex 9

4. PennyWhistle 2

5. 100 Watt Amplifier 2

Total = 15

For this many BNC connections, it is essential to have reliable 50 Ohm connections that will stand up to harsh physical use. The best results will be to use professionally made instrumentation grade BNC cables rather than buy the tools and learn to make the cables yourself. At Fry's, these quality cables are in the instrumentation section and are branded as "Pomona". From the Pomona data sheet that can be found here: Pomona Model 2249 Cable Assembly with BNC Male on Each End. The advantage over hand built cables are as follows:

  • The molded strain relief is directly bonded to the cable jacket for superior strength and durability.
  • Teflon insulation and nickel tarnish resistant outer shells used in the BNC connector provide long life and reliability.
  • Gold plated center contacts assure the most noise free connection possible.
  • The connectors and cable are impedance matched.

The length of the Pomona cables are the length in the model number plus 3.37 in or 85.60 mm on each end for the strain relief and connector. The finished 3-D layout will determine number of each length needed.

Complete W9KFB Transceiver Rear view

Software Installation

All software listed here excluding Fldigi is for Windows systems only. Other software is under development for other operating systems see: HPSDR related software

PowerSDR

For installation instructions go to the Quick Startup Guide and scroll down to "PowerSDR Software Installation", then follow the directions given there.

KISS Konsole

You must try this program as it was written to be a simple interface to the Mercury and Penelope boards. You can find information on downloading and operation at KISS Konsole.

com0com

This program is required to allow programs to communicate frequency , mode, CW and PTT data. It is required software that must be installed to operate the digital modes using Fldgi. Go to [3]to learn about and install com0com.

Virtual Audio Cable

Other than the operating system, this is the only program that is listed on the BOM that must be purchased. The trial version might be used to get familiar with the program, but it is not usable on the air. With out this program you would have to use your built in sound card and external cables which can pick up RF signals. It is a much cleaner installation to use this program. Cost $39.99 USD. Go to this website to purchase and download [4].

Fldigi

This program is required to get operating on digital modes. Follow the recommended settings given below and you should not have any problems. First install the program per the instructions on this web site [5].

Optional Software

CW Skimmer

Complete Bill of Material (BOM)

W9KFB's Complete Transceiver Block Diagram
Part Name Price ($US)
Antec NSK2480 Case and power supply 100.00
Intel D945GCLF2D Motherboard & CPU 80.61
Corsair DDR2 2GB PC3500 memory module 19.99
250GB Hard Drive 32.00
Microsoft Windows XP Home Edition SP2B for System Builders 86.91
iCube Portable Speaker 3.90
Pomona BNC 2249-C-6 cables (5 at 14.98 each) 74.90
HPSDR Components 936.33+TBD
Misc. Small parts (nuts, bolts, standoffs, carbide drill bit for drilling steel, audio and PTT jacks & cables, BNC antenna connector 30.00
TOTAL 1364.64+TBD

Optional components and upgrades

Some of the matching accessories for the W9KFB complete HPSDR transceiver
  • indicates this item was included in the build of this transceiver
Part Name Price ($US)
Hitachi Deskstar P7K500 500GB Hard Drive 54.97
Kingston 64 GB Solid State Drive* 150.00
External Optical Drive Sony DVD/CD Rewritable Drive Model DRX-840U* 99.99
Virtual Audio Cable* 39.99
Logitech USB Desktop Microphone* 29.99
PowerMate Griffin Knob* 45.00
Gyration Air Go Mouse Plus & Full Size Keyboard * 149.99

Performance Testing

W9KFB's transceiver test bench with a HP8656B Signal Generator and HP 3586B Level Meter

TX Power output

Band MW
160 Meters 623
80 Meters 645
40 Meters 623
30 Meters 590
20 Meters 543
17 Meters 492
15 Meters 464
12 Meters 436
10 Meters 408
6 Meters 157

Internally generated RX signals

Band #, Max -dBm
160 Meters 5, 112
80 Meters 4, 110
40 Meters 4, 112
30 Meters 2, 125
20 Meters 0
17 Meters 1, 120
15 Meters 6, 112
12 Meters 1, 120
10 Meters 37, 92
6 Meters 100+, 86


RX Two-tone IMD Level & Dynamic Range

Band -dBm, DR dB
160 Meters 50.7, 74.3
80 Meters 60.0, 65
40 Meters 63.9, 61.1
30 Meters 52.0, 71
20 Meters 59.3, 59.
17 Meters 61.1
15 Meters 47.8, 76.2
12 Meters
10 Meters 42.3, 81.2
6 Meters 52.3, 69.3

W9KFB Complete HPSDR Transceiver, serial number 2009-0001

Performance shown in ARRL format.

Software: PowerSDR v1.10.4+ BaseSVN 2025 (KD5TFD 14Jul2009)
Specifications Measured in the W9KFB Lab
Frequency coverage: Receive, 0.01-55 MHz; Receive, as specified.
Transmit, 1.8-2, 3.5-4, 5.3305, 5.3465, Transmit, as specified.
Transmit, 5.3665, 5.3715, 5.4035, 7-7.3, 10.1-10.15,
Transmit, 14-14.35, 18.068-18.168, 21-21.45, 24.89-
Transmit, 24.99, 28-29.7, 50-54 MHz.
Power requirement: 100-250 V ac, 50-60 Hz; Receive, 0.4 A (typical); Transmit, 0.4 A (max). tested at 125 V ac.
Modes of operation: LSB, USB, DSB, CWL, CWU, FMN, AM, SAM, SPEC, DIGL, DIGU, DRM. As specified.
ADC overload: +8dBm (preamp off), -12dBm (preamp on) ADC overload:, +11dBm (preamp off), -9dBm (preamp on)
MDS (500Hz) 1.8MHz- 54MHz: -118dbm (preamp off), -138dBm (preamp on) MDS (500Hz) 1.8MHz.: -114dbm (preamp off), n/a (preamp on)
MDS (500Hz) 3.5MHz,: -113dbm (preamp off), -129dBm (preamp on)
MDS (500Hz) 14.MHz.: -103dbm (preamp off), -122dBm (preamp on)
MDS (500Hz) 30.0MHz: n/a (preamp off), -117dBm (preamp on)
BDR (5KHz, 1dB Gain Compression): 119dB (ADC overload limited not phase noise limited) BDR (20KHz, 1dB Gain Compression) at 3.5 MHz: 105dB (preamp off), 101dB (preamp on)
BDR (20KHz, 1dB Gain Compression) at 14.0MHz: 101dB (preamp off), 119dB (preamp on)
BDR (20KHz, 1dB Gain Compression) at 30.0 MHz: n/a (preamp off), 124dB (preamp on)
BDR (5KHz, 1dB Gain Compression) at 3.5 MHz: 105dB (preamp off), 121dB (preamp on)
BDR (5KHz, 1dB Gain Compression) at 14.0MHz: 75dB (preamp off), 104dB (preamp on)
BDR (5KHz, 1dB Gain Compression) at 30.0MHz: n/a (preamp off), 119dB (preamp on)

MDS= Minimum Discernible Signal, BDR= Blocking Dynamic Range