Patented 2.8 Kw S-Band GaN Solid-State Pulsed High-Power Amplifier
Thermal management has always been a major challenge in transistor based pulsed amplifiers. As heat builds up the noise rises and gain decreases diminishing efficient performance. This problem has been exacerbated due to the availability of higher output devices.
Significant problems with pulsed amplifier designs have included:
1. Waste heat dissipation and its detrimental distortion decreasing overall system efficiency (input power vs output power).
2. Excessive weight and large overall size. Higher power densities generate excessive heat that have required heavy, bulky external thermal transfer methods such as heat sinks, fans, or cooling liquids. Size and weight issues limit applications such as airborne.
3. Requirement of a large high-current DC power supply
4. Loss of amplifier gain and increase in signal noise and distortion as component temperatures rise, possibly resulting in a forced shut down making it unreliable in critical situations.
WDS Radar pulsed amplifier methodologies have eliminated waste heat and improved efficiency by using patented proprietary DC high-speed switching techniques. The result of this high-speed switching significantly reduces energy consumption, eliminates waste heat and its detrimental distortion, and significantly improves power efficiency. The size of the DC power supply can be greatly reduced by a factor of four. These methodologies solve the challenges of thermal management. The elimination of waste heat also eliminates the need for bulky, heavy heat sinks, fans, or cooling liquids. This allows for a crucial and significant reduction in the overall weight and size of the amplifier.
| ELECTRICAL SPECIFICATIONS S-BAND | Min | Max | Unit |
| Operating Frequency | 2700 | 3100 | Mhz |
| Power Output @ 10% Duty | 2800 | Watts/dBm | |
| Pin for maximum rated power out | -3.0 | -0- | dbM |
| Duty Cycle Standard | 10% | % | |
| Pulse Width Standard | 0.5 | 100 µs | µs |
| PRF | 0.1 | 2 | kHz |
| Pulse Droop at 100 µs | 0.2 | 0.8 | dBm |
| Operating Voltage | 48 | 51 | VDC |
| RF Input Connector | SMA Female | ||
| RF Output Connector | 7/16 DIN | ||
| DC Power & Control Connector | 7 position Sub D | ||
| DC Power Consumption | 125 | Watts/typ | |
| VSWR Input/Output | 1.5 to 1 typ | ||
| Pre-Amp Not Required |
| MECHANICAL/SINGLE MODULE | Wide | Deep | High |
| Dimensions w/Base Plate (Inches) | 14.125 | 12.250 | 2.50 |
| Weight | 13.1 lbs | ||
| Material | 6061 T-6 Aluminum | ||
| Finish | High temp ceramic coating over electrolysis nickel plate | ||
| ENVIRONMENTAL CHARACTERISTICS | Min | Max |
| Non-Operating/Storage | -40 C | +80 C |
| Operating Ambient Temperature | 0 C | +73 C |
| Relative Humidity Non-Condensing | 90% |
System Protection
Low/High Voltage Shutdown
Over Temperature
Duty Cycle Limit
VSWR Limit
Communication For Status Forward/Faults Forward/Shutdown
On-Board Web Interface via Ethernet
RJ-45 Connector
Options
Higher Pulse Width/Duty Cycle
Primary Power
Multi-Combined Units
Circular Military Power Connector
Military Specifications
Pulse Performance
500 ns @ 1 KHz
20 µs @ 1 KHz
50 µs @ 1 KHz
Temperature Performance Over Time
Note: Tested on lab bench independent of attachments.
All values listed are typical and are subject to change. Data should be used for general reference only. Other operational parameters are available upon request from WDS Radar.
WDS Radar | Evergreen, CO | 720-837-9468 M