Amkor Technology, a provider of outsourced semiconductor assembly and test (OSAT) services, has developed the double-sided, molded ball grid array (DSMBGA) technology. With the introduction of 5G, cellular frequency bands have increased considerably, requiring innovative solutions for the packaging of RF front-end modules for smartphones and other 5G-enabled devices. Amkor’s double-sided packaging technology has vastly increased the level of integration for RF front-end modules used in smartphones and other mobile devices. Common RF front-end modules consist of an LNA (low noise amplifier), a power amp, an RF switch, RF filters and duplexers.
Amkor’s advanced SiP design rules and innovative DSMBGA technology enable the integration of additional components—such as antenna tuners and passive components—where device motherboard real estate is at a premium. This creates the most advanced and compact RF front-end module on the market today. With additional power amplification and filtering circuitry, DSMBGA improves signal integrity and reduces losses, resulting in improved Rx/Tx amplification—which translates into reduced system power requirements.
Amkor also applies state-of-the-art conformal and compartmental shielding for EMI isolation and attenuation and implements in-line RF testing to deliver the most robust and cost-effective assembly technology in the industry.
Expanding on years of experience in delivering world-class, advanced System in Package (SiP) technology, Amkor was the first OSAT to offer DSMBGA and continues to pave the way for further breakthroughs.
Giel Rutten, Amkor President and Chief Executive Officer said that with their DSMBGA platform, they've established a preferred advanced packaging solution for this domain. Applying leading-edge design rules for 3D component placement and double-sided molding—together with conformal and compartmental shielding and in-line RF testing—delivers best-in-class integration levels in a small form factor in a high yield manufacturing process.
The advanced packaging market for 5G RF FEM is projected to reach US $2.3 billion by 2026, representing a 30% compound annual growth rate (CAGR) according to Yole Développement (Yole), SA, an industry consulting firm.
According to Antoine Bonnabel, Technology & Market Analyst, RF Devices and Technology at Yole there has been a change in frequencies with the arrival of 5G, adding frequency bands above 3 GHz in FR1, and mmWave in FR2. This and the system-level trend have had a profound impact on both the number of components and the technology platforms on which they are built.
This growing number of new frequencies, combined with the variety of multiplexing methods, significantly increases the complexity of the RF front end. Integration using SiP allows customers to design, tune and test RF sub-systems, allowing for a reduction in design iterations and an accelerated time-to-market.
In addition to its formidable SiP capacity and DSMBGA technology, Amkor has developed an extensive toolset to maximize performance and to address the sophisticated packaging formats required to productize 5G applications. Some of these tools include Antenna in Package (AiP), substrate-embedded die, wafer-level SiP and a variety of RF shielding options.
This toolset, combined with the company’s expertise in RF module design, characterization and bench test, uniquely positions Amkor to serve customers who want to outsource the challenges (including substantial investment) associated with combining multiple ICs with advanced package assembly and test technologies for 5G networks.
As demand for packages that support 5G increases, Amkor supports this growth with the successful implementation of DSMBGA technology. Amkor has been in high-volume markets with DSMBGA for more than a year and is a leader in RF package design, integration and test. Amkor continues to innovate in DSMBGA and other advanced SiP technologies to capture opportunities in the RF market.