Features
- VHF – 3.0 GHz Operation
- 30 W Peak Power Capability
- > 15 dB Small Signal Gain
- > 28% Drain Efficiency
CGH27030
30-W; DC – 6.0-GHz; 28-V; GaN HEMT
Note: CGH27030F is Not Recommended for New Designs. Refer to CG2H40025F
Wolfspeed’s CGH27030 is a gallium-nitride (GaN) high-electron-mobility transistor (HEMT) designed specifically for high-efficiency; high-gain and wide-bandwidth capabilities; which makes the CGH27030 ideal for VHF; Comms; 3G; 4G; LTE; 2.3-2.9GHz WiMAX and BWA amplifier applications. The transistor is available in screw-down flange; solder-down pill packages; and a 3mm x 4mm; surface mount; dual-flat-no-lead (DFN) package.
Products
CGH27030
No filters selected, showing all 5 products
CGH27030
Product SKU | Buy Online | Request Sample | Data Sheet | CAD Model | Recommended For New Design? | Technology | Frequency Min | Frequency Max | Peak Output Power | Gain | Efficiency | Operating Voltage | Form | Package Type |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
CGH27030F | No | GaN on SiC | DC | 6 GHz | 30 W | 15 dB | 28% | 28 V | Packaged Discrete Transistor | Flange | ||||
CGH27030P | Yes | GaN on SiC | DC | 6 GHz | 30 W | 15 dB | 28% | 28 V | Packaged Discrete Transistor | Pill | ||||
CGH27030F-AMP | Yes | GaN on SiC | DC | 6 GHz | 30 W | 15 dB | 28% | 28 V | Evaluation Board | Flange | ||||
CGH27030S-AMP1 | Yes | GaN on SiC | 1.8 GHz | 2.2 GHz | 30 W | 18 dB | 33% | 28 V | Evaluation Board | Surface Mount | ||||
CGH27030S | Yes | GaN on SiC | DC | 6 GHz | 30 W | 18 dB | 33% | 28 V | Packaged Discrete Transistor | Surface Mount |
Applications
- VHF; Comms; 3G; 4G; LTE; 2.3-2.9 GHz WiMAX and BWA amplifier applications.
Documents, Tools & Support
- Technical & Sales Documents
- Tools & Support
- Compliance
Documents
Apply Filters
Document Type | Document Name |
|---|---|
| Design Files | |
| Design Files | |
| Application Notes | |
| Application Notes | |
| Application Notes | |
| Application Notes | |
| Application Notes | |
| Data Sheets | |
| Data Sheets | |
| S-parameters | |
| S-parameters | |
| Technical Papers & Articles | by Raymond S. Pengelly – William Pribble – Thomas Smith
This Simulation of power amplifiers (PAs) for modern wireless base station and small cell systems is an essential part of the design process. At a cell site – the PA consumes the bulk of the dc power – generates the most heat – and thus represents the greatest operational cost. Maximum PA efficiency is a necessity to manage these costs – which is a sizeable challenge in a PA that also must be highly linear to support the complex multilevel modulation types and wide bandwidths used for current and developing wireless transmission standards. Accurate simulation allows the PA designer to meet these challenges by exploring the available design options and then optimizing the circuit that is selected for the application.
|
| Technical Papers & Articles | by Ray Pengelly – Simon Wood – Jim Crescenzi – This article describes a WiMAX power amplifier – which achieves high performance using the latest device technologies and design techniques.
|
| Technical Papers & Articles | by Marco J. Pelk – W. C. Edmund Neo – John R. Gajadharsing – Raymond S. Pengelly – Leo C. N. de Vreede – A three-way Doherty 100-W GaN base-station power amplifier at 2.14 GHz is presented.
|
| Technical Papers & Articles | by Raymond S. Pengelly – Simon M. Wood – James W. Milligan – Scott T. Sheppard – and William L. Pribble
|
| Technical Papers & Articles | by Raymond S. Pengelly – Brad Millon – Donald Farrell – Bill Pribble – and Simon Wood
Presentation from the 2008 IEEE MTT-S International Microwave Symposium (IMS) Workshop on Challenges in Model-Based HPA DesignThis presentation discusses attributes of GaN HEMTs – Wolfspeed GaN HEMT models – design examples (Broadband CW Amplifiers and Linear WiMAX Amplifier) – and future model improvements.
|
| Technical Papers & Articles | by Donald A. Gajewski – Scott Sheppard – Simon Wood – Jeff B. Barner – Jim Milligan – and John Palmour.
This paper discusses the reliability performance of Wolfspeed GaN/AlGaN high electron mobility transistor (HEMT) MMIC released process technologies – fabricated on 100 mm high purity semi-insulating (HPSI) 4H-SiC substrates.
|
| Technical Papers & Articles | by Donald A. Gajewski – Scott Sheppard – Tina McNulty – Jeff B. Barner – Jim Milligan and John Palmour
This paper reports the reliability performance of the Wolfspeed – GaN/AlGaN HEMT MMIC process technology – fabricated on 100 mm high purity semi-insulating (HPSI) 4H-SiC substrates.
|
| Technical Papers & Articles | by Ildu Kim – Jangheon Kim – Junghwan Moon – Jungjoon Kim – and Bumman Kim
Demonstrating a highly efficient Hybrid Envelope Elimination and Restoration transmitter for IEEE 802.16e Mobile WiMAX applications using a highly efficient saturated Power Amplifier (PA). For the optimum H-EER operation – the PA has been designed to have a maximum PAE at the average Vds region by using 10 W (P3dB ) GaN High Electron Mobility Transistor.
|
| Product Catalog | |
| Sales Terms |
Knowledge Center
Wolfspeed RF GaN meets 5G demands on PA design
Wolfspeed GaN on SiC products can replace inefficient silicon parts in 5G cellular transmitter amplifiers, achieving higher linearization, greater power density and improved thermal conductivity.
SiC vs GaN vs Si: Find The Right Fit For Your Application
Explore Wolfspeed Silicon Carbide Power and GaN on Silicon Carbide RF solutions to enable your high performance systems.