Datasheet HMC618ALP3E (Analog Devices)
| Fabricante | Analog Devices |
| Descripción | GaAs SMT pHEMT Low Noise Amplifier, 1.2 - 2.2 GHz |
| Páginas / Página | 14 / 1 — HMC618ALP3E. GaAs SMT pHEMT LOW NOISE. AMPLIFIER, 1.2 - 2.2 GHz. Typical … |
| Revisión | A |
| Formato / tamaño de archivo | PDF / 961 Kb |
| Idioma del documento | Inglés |
HMC618ALP3E. GaAs SMT pHEMT LOW NOISE. AMPLIFIER, 1.2 - 2.2 GHz. Typical Applications. Features. Functional Diagram
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HMC618ALP3E
v01.0519
GaAs SMT pHEMT LOW NOISE AMPLIFIER, 1.2 - 2.2 GHz Typical Applications Features
The HMC618ALP3E is ideal for: Noise Figure: 0.75 dB T • Cel ular/3G and LTE/WiMAX/4G Gain: 19 dB M • BTS & Infrastructure OIP3: 36 dBm Single Supply: +3V to +5V • Repeaters and Femto Cel s E - S 50 Ohm Matched Input/Output • Public Safety Radios IS 16 Lead 3x3mm SMT Package: 9 mm2 O
Functional Diagram General Description
W N The HMC618ALP3E is a GaAs pHEMT MMIC O Low Noise Amplifier that is ideal for Cel ular/3G and LTE/WiMAX/4G basestation front-end receivers operating between 1.2 - 2.2 GHz. The amplifier has S - L been optimized to provide 0.75 dB noise figure, R 19 dB gain and +36 dBm output IP3 from a single IE supply of +5V. Input and output return losses are excel ent and the LNA requires minimal external LIF matching and bias decoupling components. The P HMC618ALP3E shares the same package and M pinout with the HMC617LP3E 0.55 - 1.2 GHz LNA. A The HMC618ALP3E can be biased with +3V to +5V and features an external y adjustable supply current which al ows the designer to tailor the linearity performance of the LNA for each application. The HMC618ALP3E offers improved noise figure versus the previously released HMC375LP3(E) and the HMC382LP3(E).
Electrical Specifications T = +25° C, Rbias = 470 Ohm for Vdd1 = Vdd2 = 5V A
Vdd = 5 Vdc Parameter Units Min. Typ. Max. Min. Typ. Max. Min. Typ. Max. Frequency Range 1200 - 1700 1700 - 2000 2000 - 2200 MHz Gain 19 23 16 19 13.5 17 dB Gain Variation Over Temperature 0.012 0.008 0.008 dB/°C Noise Figure 0.65 0.85 0.75 1.1 0.85 1.15 dB Input Return Loss 22.5 18 19.5 dB Output Return Loss 13 12.5 10 dB Output Power for 1 dB 19 16.5 20 18 20 dBm Compression (P1dB) Saturated Output Power (Psat) 20.5 20.5 20.5 dBm Output Third Order Intercept (IP3) 29.4 33.5 29.5 35 30.4 35.5 dBm Supply Current (Idd) 89 118 89 118 89 118 mA * Rbias resistor sets current, see application circuit herein Information furnished by Analog Devices is believed to be accurate and reliable. However, no For price, delivery, and to place orders: Analog Devices, Inc., responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106
1
rights of third parties that may result from its use. Specifications subject to change without notice. No Phone: 781-329-4700 • Order online at www.analog.com license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. Application Support: Phone: 1-800-ANALOG-D Document Outline Typical Applications Features Functional Diagram General Description Electrical Specifications 1200 to 1700 MHz Tune Gain vs. Temperature Gain vs. Temperature Input Return Loss vs. Temperature Input Return Loss vs. Temperature Output Return Loss vs. Temperature Output Return Loss vs. Temperature Reverse Isolation vs. Temperature Reverse Isolation vs. Temperature Noise Figure vs. Temperature Noise Figure vs. Temperature Output P1dB vs. Temperature Output P1dB vs. Temperature Psat vs. Temperature Psat vs. Temperature Output IP3 vs. Temperature Output IP3 vs. Temperature 1700 to 2200 MHz Tune Broadband Gain & Return Loss Gain vs. Temperature Gain vs. Temperature Input Return Loss vs. Temperature Output Return Loss vs. Temperature Reverse Isolation vs. Temperature Noise Figure vs Temperature Output P1dB vs. Temperature Psat vs. Temperature Output IP3 vs. Temperature Output IP3 and Idd vs. Supply Voltage @ 1750 MHz Output IP3 and Idd vs. Supply Voltage @ 1750 MHz Output IP3 and Idd vs. Supply Voltage @ 2100 MHz Output IP3 and Idd vs. Supply Voltage @ 2100 MHz Power Compression @ 1750 MHz Power Compression @ 1750 MHz Power Compression @ 2100 MHz Power Compression @ 2100 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 1750 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 1750 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 2100 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 2100 MHz Output IP3 vs. Rbias @ 1750 MHz Gain, Noise Figure vs. Rbias @ 1750 MHz Output IP3 vs. Rbias @ 2100 MHz Gain, Noise Figure vs. Rbias @ 2100 MHz Absolute Bias Resistor Range & Recommended Bias Resistor Values for Idd Absolute Maximum Ratings Typical Supply Current vs. Vdd Outline Drawing Package Information Pin Descriptions Evaluation PCB 1700 to 2200 MHz Tune Application Circuit Evaluation PCB Ordering Information List of Materials 1200 to 1700 MHz Tune Application Circuit Evaluation PCB Ordering Information List of Materials
v01.0519
GaAs SMT pHEMT LOW NOISE AMPLIFIER, 1.2 - 2.2 GHz Typical Applications Features
The HMC618ALP3E is ideal for: Noise Figure: 0.75 dB T • Cel ular/3G and LTE/WiMAX/4G Gain: 19 dB M • BTS & Infrastructure OIP3: 36 dBm Single Supply: +3V to +5V • Repeaters and Femto Cel s E - S 50 Ohm Matched Input/Output • Public Safety Radios IS 16 Lead 3x3mm SMT Package: 9 mm2 O
Functional Diagram General Description
W N The HMC618ALP3E is a GaAs pHEMT MMIC O Low Noise Amplifier that is ideal for Cel ular/3G and LTE/WiMAX/4G basestation front-end receivers operating between 1.2 - 2.2 GHz. The amplifier has S - L been optimized to provide 0.75 dB noise figure, R 19 dB gain and +36 dBm output IP3 from a single IE supply of +5V. Input and output return losses are excel ent and the LNA requires minimal external LIF matching and bias decoupling components. The P HMC618ALP3E shares the same package and M pinout with the HMC617LP3E 0.55 - 1.2 GHz LNA. A The HMC618ALP3E can be biased with +3V to +5V and features an external y adjustable supply current which al ows the designer to tailor the linearity performance of the LNA for each application. The HMC618ALP3E offers improved noise figure versus the previously released HMC375LP3(E) and the HMC382LP3(E).
Electrical Specifications T = +25° C, Rbias = 470 Ohm for Vdd1 = Vdd2 = 5V A
Vdd = 5 Vdc Parameter Units Min. Typ. Max. Min. Typ. Max. Min. Typ. Max. Frequency Range 1200 - 1700 1700 - 2000 2000 - 2200 MHz Gain 19 23 16 19 13.5 17 dB Gain Variation Over Temperature 0.012 0.008 0.008 dB/°C Noise Figure 0.65 0.85 0.75 1.1 0.85 1.15 dB Input Return Loss 22.5 18 19.5 dB Output Return Loss 13 12.5 10 dB Output Power for 1 dB 19 16.5 20 18 20 dBm Compression (P1dB) Saturated Output Power (Psat) 20.5 20.5 20.5 dBm Output Third Order Intercept (IP3) 29.4 33.5 29.5 35 30.4 35.5 dBm Supply Current (Idd) 89 118 89 118 89 118 mA * Rbias resistor sets current, see application circuit herein Information furnished by Analog Devices is believed to be accurate and reliable. However, no For price, delivery, and to place orders: Analog Devices, Inc., responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106
1
rights of third parties that may result from its use. Specifications subject to change without notice. No Phone: 781-329-4700 • Order online at www.analog.com license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. Application Support: Phone: 1-800-ANALOG-D Document Outline Typical Applications Features Functional Diagram General Description Electrical Specifications 1200 to 1700 MHz Tune Gain vs. Temperature Gain vs. Temperature Input Return Loss vs. Temperature Input Return Loss vs. Temperature Output Return Loss vs. Temperature Output Return Loss vs. Temperature Reverse Isolation vs. Temperature Reverse Isolation vs. Temperature Noise Figure vs. Temperature Noise Figure vs. Temperature Output P1dB vs. Temperature Output P1dB vs. Temperature Psat vs. Temperature Psat vs. Temperature Output IP3 vs. Temperature Output IP3 vs. Temperature 1700 to 2200 MHz Tune Broadband Gain & Return Loss Gain vs. Temperature Gain vs. Temperature Input Return Loss vs. Temperature Output Return Loss vs. Temperature Reverse Isolation vs. Temperature Noise Figure vs Temperature Output P1dB vs. Temperature Psat vs. Temperature Output IP3 vs. Temperature Output IP3 and Idd vs. Supply Voltage @ 1750 MHz Output IP3 and Idd vs. Supply Voltage @ 1750 MHz Output IP3 and Idd vs. Supply Voltage @ 2100 MHz Output IP3 and Idd vs. Supply Voltage @ 2100 MHz Power Compression @ 1750 MHz Power Compression @ 1750 MHz Power Compression @ 2100 MHz Power Compression @ 2100 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 1750 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 1750 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 2100 MHz Gain, Power & Noise Figure vs. Supply Voltage @ 2100 MHz Output IP3 vs. Rbias @ 1750 MHz Gain, Noise Figure vs. Rbias @ 1750 MHz Output IP3 vs. Rbias @ 2100 MHz Gain, Noise Figure vs. Rbias @ 2100 MHz Absolute Bias Resistor Range & Recommended Bias Resistor Values for Idd Absolute Maximum Ratings Typical Supply Current vs. Vdd Outline Drawing Package Information Pin Descriptions Evaluation PCB 1700 to 2200 MHz Tune Application Circuit Evaluation PCB Ordering Information List of Materials 1200 to 1700 MHz Tune Application Circuit Evaluation PCB Ordering Information List of Materials