This article aims to delve into the highly market-driven terminology form multiple perspectives. Starting from the inception of customer demands, it progressively covers the procurement of components, selection of technological paths, determination of packaging processes, and ultimately, the complete manufacturing process of optical modules. This is intended to offer readers a clearer overall understanding of optical modules.<\/p>\n
The end-to-end process from demand to the completion of optical module design.<\/h2>\n
This article descibes the end-to-end manufacturing process of optical modules, starting from customer demands and proceeding through material selection, design, and production. The article systematically analyzes numerous terms, technologies, and categories within the optical module field. At the same time,\u00a0 it also briefly introducing industry development trends.<\/p>\n
<\/p>\n
<\/b>\u00a0Requirements analysis<\/h3>\n
Using the data center as an example, the customer requirements is a transmission distance of 500 meters at a speed of 100G, utilizing a QSFP28<\/a> interface, while also considering the overall system cost. This concise requirement encompasses every key detail in optical module design and manufacturing.<\/p>\n Selection 1: Packaging Method and Process Route.<\/strong> We can choose between hermetic packaging options such as TO-CAN, BOX, and butterfly, or non-hermetic packaging options like COB, COC, etc.<\/p>\n Selection 2\uff1aTypes of optical module.<\/strong>\u00a0The various types such as VCSEL, DFB, EML, or narrow linewidth tunable can be choose.<\/p>\n Selection 3: Design Route.<\/strong> It can be a single-channel or multi-channel design.<\/p>\n Selection 4: Modulation Format.<\/strong> It can be NZR, PAM4, Coherent Modulation (such as QPSK, 16QAM, 64QAM, etc.)<\/p>\n Selection 5: Future development.<\/strong> Considering the continuously increasing data rates, outsourcing optical engines, and emerging technologies like silicon photonics.<\/p>\n <\/p>\n These choices are directly related to several key performance indicators required by the product, and they are closely linked to the overall reliability and cost of the final product. In the competitive field of optical modules, it\u2019s necessary to find the optimal balance among a combination of parameters.<\/p>\n This involves pursing performance aspects such as data rates, small form factors, and long transmission distances.\u00a0 It also entails addressing power consumption and thermal management challenges. Addressing thermal management concerns may, in turn, raise cost considerations. Managing costs, in turn, involves risks related to stability and reliability, among other factors.<\/p>\n Therefore, despite the standardization of packaging, appearance, and electrical interfaces, the design and manufacturing of optical modules still require extensive experience. Understanding customer requirements and striking a balance between performance, power consumption, cost, and reliability are the essence of a company\u2019s core competitiveness in the optical module industry.<\/p>\n In this challenging process, designers need to navigate various technical and business considerations while maintaining optimal performance. They need to ensure that the product remains competitive in the market with outstanding performance.<\/p>\n <\/p>\n Based on customer requirements and the outdoor environments, where laser chips are susceptible to vapor corrosion and temperature fluctuations that can significantly affect wavelength, we are considering adopting a hermetic sealing solution. This solution involves sealing the laser chip within a metal enclosure, filling the enclosure with inert gas, and including a sealed window for laser transmission. Depending on factors such as transmission distance, chip heat generation, cost requirements, and the number of channels, we can choose different hermetic sealing methods.<\/p>\n (1) TO-CAN Package<\/strong><\/p>\n The laser diode is placed on a small heat sink (heat spreader) and connected via wire bonds to electrical pins. Subsequently, a metal cap is sealed on to the laser diode, including a sealed window for laser transmission. TO-CAN packaging offers a compact size and relatively low cost, making it suitable for applications in the telecommunications market, such as 10km 10G\/25G transmission in areas like base station front-haul and home broadband.<\/p>\n However, due to its small size, it may not be well-suited for high-power, high-current, and long-distance transmission scenarios. This is because it is challenging to incorporate larger heat dissipation devices into such compact designs.<\/p>\n After being assembled into a TO-CAN, it essentially provides the basic packaging for the laser diode. However, the laser beam\u2019s diameter may still differ from that of the optical fiber. Further alignment and coupling with lenses and optical fibers are required to focus the majority of the energy into the optical fiber.<\/p>\n Once all the components are fully packaged, it becomes a TOSA (Transmitter Optical Subassembly). On the other end, when using a receiver chip, it is referred to as a ROSA (Receiver Optical Subassembly). Collectively, these are known as OSA (Optical Subassemblies).<\/p>\n (2) Butterfly Package<\/strong><\/p>\n To meet high-power requirements, a butterfly packaging solution can be employed. The laser diode is mounted on a larger heat sink, and a TEC (Thermoelectric Cooler) temperature control system can also be optionally used. Optical components such as lenses and isolators are also housed within the metal enclosure.<\/p>\n <\/p>\n <\/p>\n (3) BOX Package<\/strong>:<\/p>\n The BOX package is a specialized form of butterfly packaging designed to meet multi-channel requirements. Inside the BOX package, multiple laser diodes are integrated, and they are transmitted through a single optical fiber. This type of packaging is suitable for applications that have higher demands for temperature control, hermetic sealing, and reliability. Multi-channel issues will be discussed in more detail later, but they are briefly mentioned here.<\/p>\n <\/p>\n <\/p>\n <\/p>\n As optical modules are widely utilized in the market, data centers have equipped themselves with air conditioning and environmental monitoring devices. Compared to the outdoor telecommunications market, data centers offer a more optimized working environment. This widespread use of optical modules has placed higher demands on cost control, leading to the gradual emergence of non-hermetic packaging technologies. This technology continues to evolve, with a continuous improvement in reliability, and its applicable scenarios are also expanding.<\/p>\n Non-hermetic packaging, in simple terms, involves directly attaching or soldering optical chips onto a printed circuit board (PCB) and using adhesive materials like epoxy resin for basic sealing. This approach reduces the need for many auxiliary components, thus improving cost-effectiveness and integration.<\/p>\n COB (Chip on Board) packaging is indeed a typical form of non-hermetic packaging. In COB packaging, components such as laser chips, laser arrays, and receiver arrays are directly attached or bonded onto a PCB (printed circuit board) substrate, achieving a compact form of packaging. This approach eliminates some protective measures and auxiliary devices, making it a relatively cost-effective choice.<\/p>\n For optical modules operating at 25Gbps and below, single-channel TO or butterfly-packaged optical transceivers components are typically soldered onto a PCB board. However, for high-speed optical modules operating at 40Gbps and above, there is often a need to use multiple channels in parallel due to limitations imposed by laser diode speed. For instance, 40Gbps can be achieved by aggregating four 10Gbps channels, and 100Gbps can be realized by combining four 25Gbps channels.<\/p>\n This places higher demands on packaging, including parallel optical design, managing high-speed electromagnetic interference, reducing physical size, and addressing heat dissipation issues, among others. COB packaging is a solution well-suited to meet these demands. It allows for the integration of TIA (Transimpedance Amplifier) \/ LA(Limiting Amplifier) chips, laser arrays, and receiver arrays into a compact package, enabling miniaturization of the module.<\/p>\n In summary, hermetic sealing provides a robust protective barrier constructed with metal and glass, making it suitable for various environmental conditions. However, non-hermetic packaging, when operating within controlled working environments, can optimize costs while meeting specific requirements.<\/p>\n <\/p>\n When selecting optical chips, it is necessary to consider multiple factors comprehensively, including transmission distance, modulation methods, and cost. Additionally, the state of the supply chain is also an important consideration because certain popular products may experience shortages, delays, or delivery postponements during the early stages of production.<\/p>\n The semiconductor industry operates with significant economies of scale, and most chip manufacturers prioritize supplying large customers, while smaller manufacturers may need to seek alternative suppliers or solutions.<\/p>\n Due to differences in demand, there can be significant price variations when acquiring chips among optical module companies. Some larger companies with high demand may secure a price advantage of 20-30% lower than smaller manufacturers, making it a critical competitive factor in the optical module industry. Therefore, in the process of chip selection and procurement, supply chain and pricing factors also need to be carefully considered.<\/p>\n <\/p>\n VCSEL chips are a cost-effective choice with a larger emission angle, typically used in conjunction with multi-mode fibers. However, multi-mode fiber tends to be more expensive. When considering the overall system cost, it is more suitable for sort-distance applications, such as a few meters for AOC (Active Optical Cable) and approximately 100 meters for SR (Short-Range) optical modules.<\/p>\n DFB (Distributed Feedback) chips are processed with gratings on top of the original FP (Fabry-Perot) laser to achieve more precise wavelength selection, thereby improving the accuracy of the output wavelength. The DFB chips have a narrower emission angle, enabling more efficient optical path coupling. As a result, DFB chips are more commonly used in medium to long-distance applications, such as 500 meters or 2 kilometers, and they offer a relatively moderate cost option.<\/p>\n EML (Electro-Absorption Modulated Laser) chips are a higher-cost option, consisting of a laser chip (which can be DFB, DBR, etc.) and an external electro-absorption modulator. During operation, the laser chip remains in a continuous emission state, and the signal output of the EML laser is controlled by toggling the state of the absorption chip. The advantage of using EML lies in the stable operation of the laser chip, resulting in a purer emitted wavelength. Even after modulation by the external modulator and long-distance transmission, the signal quality remains high.<\/p>\n EML is suitable for long-distance transmission applications, such as 10 kilometers, 20 kilometers, 40 kilometers, or even longer distances. However, due to the requirement for an external electro-absorption modulator and the higher quality demands associated with long-distance applications, the cost of EML chips is relatively higher than DFB chips, by as much as 50% or even more, at the same data rate.<\/p>\n <\/p>\n <\/p>\n <\/p>\n In the previous discussion, we mentioned that long-distance transmission encounters dispersion issues, and while EML (Electro-Absorption Modulated Laser) can address chirping-related problems, the inherent emission wavelength range of the laser, known as the \u2018linewidth\u2019, still persists. This issue remains prominent in ultra-long-distance ODN (Optical Distribution Network) applications, such as 80km, 100km, or even longer distances.<\/p>\n On the other hand, for ultra-long-distance trunkline transmission, the consideration of overall system cost is crucial. Laying a substantial amount of optical fiber from Beijing to Shanghai incurs significant expenses. Therefore, the introduction of DWDM<\/a> (Dense Wavelength Division Multiplexing) technology, which enables the transmission of signals at different wavelengths over a single optical fiber, greatly enhances the transmission capacity of a single fibers and reduces the overall system cost for long-haul trunklines. Meeting these dual requirements necessitates the use of tunable narrow-linewidth lasers.<\/p>\n <\/p>\n <\/p>\n The structure of a tunable narrow linewidth laser is complex, and there are various approaches to achieve it, including current control, temperature control, mechanical control, and more. Taking the external cavity mechanical control approach as an example, a grating structure is added outside the ordinary laser, and the output wavelength is adjusted through mechanical control to achieve more precise wavelength control.<\/p>\n Tunable lasers have historically found limited applications, but with the potential introduction of wavelength division multiplexing (WDM) technology in 5G front-haul, some manufacturers are exploring the possibilities of using tunable lasers. The future demand for these technologies may undergo significant changes.<\/p>\n![\"The](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72471.png\")
<\/p>\n<\/h3>\n
The Selection of Form Factor<\/h3>\n
Hermetic Packging<\/h4>\n
![\"\"](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72471.jpg\")
<\/p>\n![\"\"](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72472-1.jpg\")
<\/p>\n![\"\"](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72473.jpg\")
<\/p>\nNon-hermetic Packaging<\/strong><\/h4>\n
<\/b>Optical Chips Selection<\/b><\/strong><\/h3>\n
![\"Optical](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72474.jpg\")
<\/p>\nVCSEL Chip<\/strong><\/h4>\n
DFB Chip<\/strong><\/h4>\n
EML Chip<\/strong><\/h4>\n
![\"\"](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72472.png\")
<\/p>\nTunable Narrow-Linewidth Laser (Tunable Laser)<\/strong><\/h4>\n
![\"\"](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72473.png\")
<\/p>\n
![\"The](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72475.jpg\")
<\/p>\n![\"multi-mode](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72474.png\")
<\/p>\n![\"single-mode](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72475.png\")
<\/p>\n![\"NRZ](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72476.png\")
<\/p>\n![\"PAM4](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72477.png\")
<\/p>\n![\"\"](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72478.png\")
<\/p>\n![\"\"](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72476.jpg\")
<\/p>\n![\"Coherent](\"https:\/\/ascentoptics.com\/blog\/wp-content\/uploads\/2023\/09\/\u56fe\u72479.png\")
<\/p>\n