Renesas Electronics, a premier provider of advanced semiconductor solutions, today announced the availability of its ultralow-noise heterojunction field effect transistor (FET) product, the NE3520S03, which features the industry-leading low noise characteristics for satellite broadcast reception applications.
The new NE3520S03 FET features a semiconductor chip with an epitaxial structure (see Note 1) that speeds up the electron velocity and substantially reduces the source resistance. In addition, three-dimensional electromagnetic field analysis was used to improve the performance of the products at high frequencies in the gigahertz class, while a hollow plastic package was employed to allow easy replacement of Renesas Electronics' existing NE3517S03 product. These improvements result in a noise figure (NF) value of 0.65 decibels (dB), which is 0.05 dB lower than the existing product and among the lowest in the world for a mass produced product designed for the 20 gigahertz (GHz) band.
The new product enables manufacturers of antennas for satellite broadcasts to improve the reception sensitivity of their products with signals such as high-definition (HD) TV broadcasts.
Low-noise heterojunction FET products are used mainly in the low-noise block converter (LNB, see Note 2) of antennas for receiving satellite broadcasts and satellite data communications. They are the key devices used to amplify the extremely weak microwave signals transmitted by satellites. A single LNB employs from three to approximately 20 low-noise heterojunction FET devices, and a lower noise figure contributes to more stable reception and a higher quality picture that is more detailed.
Recently, the picture quality of TV broadcasts has risen and the number of channels has increased as digital broadcasting has become widespread worldwide. In particular, satellite broadcasting using microwave signals, which allows use of a wider bandwidth than terrestrial broadcasting, has brought advances in HD broadcasting on large numbers of channels.
Currently, the 12 GHz band is used for most satellite broadcasting. The United States, however, became in 2005 one of the first countries in the world to introduce broadcasting in the 20 GHz band, which is well suited to high-quality programming on many channels, and the market for this technology is expected to expand rapidly.
In addition to providing a wider bandwidth than the 12 GHz band, satellite broadcasting in the 20 GHz band permits the use of smaller antennas because of the shorter wavelengths it uses. On the other hand, such antennas are more susceptible to the effects of weather conditions such as rain, and the need for stable reception of satellite broadcasts has lead to increased market demand for low-noise microwave semiconductor devices for use in low-noise amplifiers in converters. The new NE3520S03 FET was developed in response to such demand and provides improved low-noise performance.
Key features of the new NE3520S03 FET:
(1) Industry-leading low-noise performance for a mass produced product
To reduce noise at ultrahigh frequencies, the new NE3520S03 employs a new epitaxial wafer structure that leverages high electron density, thin-layer technology. This increases the velocity at which the electrons move through the channels and lowers the source resistance, making possible a noise figure of 0.65 dB, which is among the lowest in the world in a mass produced product for the 20 GHz band, and an associated gain of 13.5 dB.
(2) High-frequency package optimized for 20 GHz band using three-dimensional electromagnetic field analysis
The structure of the hollow plastic package developed in 1996 by Renesas Electronics for 12 GHz low-noise heterojunction FET products, and currently the industry standard, was optimized through the use of three-dimensional electromagnetic field analysis. This made it possible to extend the usable frequency range of the device to the 20 GHz band. Fewer development man hours are required of customers replacing existing products with the NE3520S03 because the performance of the semiconductor chip can be extracted efficiently while the input/output impedance remains almost the same as that of existing 20 GHz band low-noise heterojunction FET products.
The superior cost-performance ratio of the low-noise heterojunction FET products for satellite broadcast reception introduced thus far has earned Renesas Electronics the top market share in this product category worldwide (Renesas estimate). The company intends to continue to develop superior products in response to the evolving demands of the market and to promote them aggressively.
Please refer to the separate sheet for the main specifications of the new products.
Note 1) Epitaxial structure
A multilayered structure formed on the semiconductor substrate through crystal growth. The epitaxial structure and the process technology, which fabricates the gate and ohmic electrodes, determine the frequency performance of field effect transistors.
Note 2) LNB (Low noise block converter):
A circuit block that amplifies the weak electromagnetic waves transmitted by the broadcasting satellite to a level at which they can be handled by the signal decoder in a TV receiver or set-top box (STB) and also performs frequency conversion.
Remarks
All other registered trademarks or trademarks are the property of their respective owners.
The new NE3520S03 FET features a semiconductor chip with an epitaxial structure (see Note 1) that speeds up the electron velocity and substantially reduces the source resistance. In addition, three-dimensional electromagnetic field analysis was used to improve the performance of the products at high frequencies in the gigahertz class, while a hollow plastic package was employed to allow easy replacement of Renesas Electronics' existing NE3517S03 product. These improvements result in a noise figure (NF) value of 0.65 decibels (dB), which is 0.05 dB lower than the existing product and among the lowest in the world for a mass produced product designed for the 20 gigahertz (GHz) band.
The new product enables manufacturers of antennas for satellite broadcasts to improve the reception sensitivity of their products with signals such as high-definition (HD) TV broadcasts.
Low-noise heterojunction FET products are used mainly in the low-noise block converter (LNB, see Note 2) of antennas for receiving satellite broadcasts and satellite data communications. They are the key devices used to amplify the extremely weak microwave signals transmitted by satellites. A single LNB employs from three to approximately 20 low-noise heterojunction FET devices, and a lower noise figure contributes to more stable reception and a higher quality picture that is more detailed.
Recently, the picture quality of TV broadcasts has risen and the number of channels has increased as digital broadcasting has become widespread worldwide. In particular, satellite broadcasting using microwave signals, which allows use of a wider bandwidth than terrestrial broadcasting, has brought advances in HD broadcasting on large numbers of channels.
Currently, the 12 GHz band is used for most satellite broadcasting. The United States, however, became in 2005 one of the first countries in the world to introduce broadcasting in the 20 GHz band, which is well suited to high-quality programming on many channels, and the market for this technology is expected to expand rapidly.
In addition to providing a wider bandwidth than the 12 GHz band, satellite broadcasting in the 20 GHz band permits the use of smaller antennas because of the shorter wavelengths it uses. On the other hand, such antennas are more susceptible to the effects of weather conditions such as rain, and the need for stable reception of satellite broadcasts has lead to increased market demand for low-noise microwave semiconductor devices for use in low-noise amplifiers in converters. The new NE3520S03 FET was developed in response to such demand and provides improved low-noise performance.
Key features of the new NE3520S03 FET:
(1) Industry-leading low-noise performance for a mass produced product
To reduce noise at ultrahigh frequencies, the new NE3520S03 employs a new epitaxial wafer structure that leverages high electron density, thin-layer technology. This increases the velocity at which the electrons move through the channels and lowers the source resistance, making possible a noise figure of 0.65 dB, which is among the lowest in the world in a mass produced product for the 20 GHz band, and an associated gain of 13.5 dB.
(2) High-frequency package optimized for 20 GHz band using three-dimensional electromagnetic field analysis
The structure of the hollow plastic package developed in 1996 by Renesas Electronics for 12 GHz low-noise heterojunction FET products, and currently the industry standard, was optimized through the use of three-dimensional electromagnetic field analysis. This made it possible to extend the usable frequency range of the device to the 20 GHz band. Fewer development man hours are required of customers replacing existing products with the NE3520S03 because the performance of the semiconductor chip can be extracted efficiently while the input/output impedance remains almost the same as that of existing 20 GHz band low-noise heterojunction FET products.
The superior cost-performance ratio of the low-noise heterojunction FET products for satellite broadcast reception introduced thus far has earned Renesas Electronics the top market share in this product category worldwide (Renesas estimate). The company intends to continue to develop superior products in response to the evolving demands of the market and to promote them aggressively.
Please refer to the separate sheet for the main specifications of the new products.
Note 1) Epitaxial structure
A multilayered structure formed on the semiconductor substrate through crystal growth. The epitaxial structure and the process technology, which fabricates the gate and ohmic electrodes, determine the frequency performance of field effect transistors.
Note 2) LNB (Low noise block converter):
A circuit block that amplifies the weak electromagnetic waves transmitted by the broadcasting satellite to a level at which they can be handled by the signal decoder in a TV receiver or set-top box (STB) and also performs frequency conversion.
Remarks
All other registered trademarks or trademarks are the property of their respective owners.
