Tag: CPE Supply Chain

  • CPE Chipset Diversification Accelerates in 2026: How New Silicon Entrants Are Reshaping 4G/5G Router Supply Chains and Reducing Single-Vendor Dependency for Telecom Operators

    CPE Chipset Diversification Accelerates in 2026: How New Silicon Entrants Are Reshaping 4G/5G Router Supply Chains and Reducing Single-Vendor Dependency for Telecom Operators

    The 4G/5G CPE chipset landscape is undergoing its most significant structural shift since the transition from LTE to 5G NR. After years of concentration among a handful of dominant silicon vendors, 2026 is witnessing an accelerating diversification of the modem and SoC supply chain — a development with direct implications for telecom operators, ISPs, and enterprise buyers who depend on predictable CPE pricing, stable lead times, and multi-source procurement strategies.

    The Shifting Silicon Landscape

    For much of the past five years, the CPE chipset market has been heavily concentrated. Qualcomm’s SDX series and MediaTek’s T-series have dominated 5G FWA and mobile router designs, while legacy 4G CAT4/CAT6 CPE segments have been served primarily by MediaTek, Qualcomm, and a small number of secondary suppliers including UNISOC and ASR Microelectronics. This concentration created supply chain fragility that became painfully visible during the 2021–2023 semiconductor shortage, when CPE manufacturers faced 26–52 week lead times on critical modem components.

    By mid-2026, the picture has changed materially. Three structural forces are reshaping the CPE silicon supply chain:

    • New fab capacity coming online. TSMC’s expanded mature-node capacity (28nm–12nm) and SMIC’s growing domestic Chinese wafer output have meaningfully increased the total available manufacturing bandwidth for IoT and CPE-grade chipsets. These processes are ideal for cost-sensitive CAT4/CAT6 and entry-level 5G RedCap modems.
    • Second-wave 5G chipset entrants reaching production maturity. UNISOC’s Ivy 5G platform, ASR’s 5G NR modem portfolio, and Eigencomm’s cellular IoT SoCs have moved from sampling to volume production, giving CPE OEMs and ODMs credible multi-source options for the first time.
    • RedCap creating a new silicon category. 3GPP Release 17 NR-Light (RedCap) defines a streamlined 5G modem profile that reduces die area, power consumption, and cost versus full-spec 5G NR. This has attracted new silicon entrants who see RedCap as a lower-barrier entry point into the 5G CPE market, bypassing the massive R&D investment required for full-spec eMBB modem development.

    What Multi-Source Means for Telecom Buyers

    For operators and ISPs procuring CPE at scale, chipset diversification translates into three tangible procurement benefits:

    1. Reduced single-vendor dependency risk. The ability to qualify CPE devices built on multiple chipset platforms means a supply disruption at any one silicon vendor does not halt an operator’s entire subscriber acquisition pipeline. Several Tier-1 European operators now explicitly require dual-source chipset qualification in their CPE RFPs — a clause that was virtually unheard of in 2023.

    2. Improved pricing dynamics. Genuine silicon competition at the CAT6, CAT12, and entry-level 5G tiers is beginning to exert downward pressure on BOM costs. Industry analysts estimate that RedCap CPE BOM costs could fall below $45 by late 2026, down from $60–70 in 2024, driven largely by modem chipset competition and mature-node wafer cost improvements.

    3. Regional supply optionality. The emergence of domestic Chinese chipset vendors with full 4G/5G modem portfolios creates regional supply chain optionality. Operators in markets without US export control restrictions can now source CPE devices with locally manufactured chipsets, potentially reducing logistics complexity and tariff exposure.

    The RedCap Catalyst

    5G RedCap (NR-Light) deserves special attention as the catalyst for silicon diversification. Unlike full-spec 5G eMBB modems — which require complex RF front-end architectures supporting 4×4 MIMO across multiple bands, carrier aggregation across low/mid/high bands, and 256QAM/1024QAM modulation — RedCap strips the modem specification down to a more constrained but still highly useful profile: 2 receive antennas (versus 4), 1 or 2 transmit antennas, 256QAM in downlink, and simplified carrier aggregation with a single carrier in FR1 supporting up to 20 MHz bandwidth.

    This simpler specification reduces silicon die area by approximately 60–65% compared to full-spec 5G modems. The resulting cost structure makes RedCap commercially viable for chipset vendors who could not justify the R&D investment for full-spec 5G modem development. The GSMA now projects RedCap device shipments exceeding 80 million units annually by 2028, with CPE and FWA devices representing the largest single category.

    Qualification Considerations for Operators

    While chipset diversification is broadly positive for the CPE ecosystem, operators must approach multi-source qualification with structured evaluation criteria. Key considerations include:

    • Modem-RF interoperability validation. Each modem-plus-RF-front-end combination must be validated against the operator’s specific band plan, carrier aggregation combinations, and network feature set (VoLTE/VoNR, IMS, emergency calling). A chipset that performs well in lab conditions may exhibit unexpected behavior with a specific operator’s RAN vendor configuration.
    • Firmware maturity and update cadence. Newer chipset entrants may have less mature modem firmware with respect to power management, thermal throttling, and mobility handling (cell reselection, handover). Operators should request firmware release histories and field deployment references before committing to volume orders.
    • Regulatory certification coverage. Multi-source CPE procurement must verify that each chipset variant holds the necessary regulatory certifications for the operator’s target markets — FCC (US), CE (EU), Anatel (Brazil), SRRC/CCC (China), and others as required.
    • Long-term roadmap alignment. Does the chipset vendor have a credible roadmap to 3GPP Release 18 (5G-Advanced) features including AI-native air interface optimizations and enhanced positioning? Operators investing in network upgrades need CPE silicon that will support forthcoming RAN capabilities, not just today’s feature set.

    Strategic Implications for 2026–2027

    The CPE chipset supply chain is transitioning from a seller’s market to a more balanced — and in some segments, buyer-friendly — environment. For telecom operators and ISPs, the strategic implications are clear:

    • Now is the time to qualify second-source chipsets. Operators who initiate multi-source qualification programs in 2026 will have approved alternative silicon options available before the next supply disruption — not scrambling during it.
    • RedCap should feature in every CPE RFP issued in H2 2026. Whether as a primary requirement for cost-sensitive segments or as an optional alternative for specific deployment scenarios, RedCap represents a genuine new category of CPE silicon that operators should be evaluating.
    • Silicon diversity strengthens negotiation leverage. CPE OEMs and ODMs with multi-chipset design capability — like Honlly Telecom, which maintains design references across Qualcomm, MediaTek, UNISOC, and ASR platforms — offer operators genuine procurement flexibility rather than single-source lock-in.

    As the CPE ecosystem matures through 2026, chipset diversification will increasingly differentiate the supply chain capabilities of CPE manufacturers. Operators and ISPs who proactively build multi-source silicon requirements into their procurement frameworks will be better positioned to navigate the next phase of 5G network expansion — with more predictable costs, more resilient supply chains, and more competitive CPE portfolios.

    For more information about Honlly Telecom’s multi-chipset CPE portfolio and OEM/ODM capabilities, contact our sales team at sales@xmhonlly.com.

  • WiFi Chip Prices Quadruple: What 4G/5G Router and CPE Buyers Should Know

    WiFi Chip Prices Quadruple: What 4G/5G Router and CPE Buyers Should Know

    Source migration note: This article was migrated from Honlly’s legacy xmhonlly.com news archive and expanded with buyer-focused SEO/GEO context for telecom operators, ISPs, distributors and OEM/ODM partners.

    According to a Netcom chip supplier, August 11 (2021) , t he price of Wi-Fi chips used in the terminal rose to about $17 in the third quarter, five times the price of the price of $3.50 last year.

    Now, the shortage of rising prices has spread to almost the entire semiconductor industry, and the supply of Wi-Fi module chips has been scarce for a period of time . In March, N etcom chip giant Broad Com notified customers that the chip delivery cycle would be extended to more than a year. In this context, the downstream computer terminal manufacturers have opened the hoarding mode.

    Previously, when Taiwanese industrial computer companies could only cost about 1,000 Wi-Fi chips a month, now they demand thousands a month. Each computer business is in the order to grab capacity, in case after facing no core available, had to temporarily suspend production situation.

    Currently, many devices are upgrading from Wi-Fi 5 to Wi-Fi 6, which is a significant improvement over the former, which also puts higher requirements on Wi-Fi chips. At this time, consumers are more willing to buy devices that support Wi-Fi 6 capabilities. The demand for Wi-Fi 6 chips is huge, which is one reason for the price increase of Wi-Fi chips.

    The Wi-Fi 6 supports all ISM bands at 1-6GHz and is downward compatible with multiple previous generation standards. With multiple people sharing a Wi-Fi 6 router, the transmission rate of Wi-Fi 6 can be 37% higher than Wi-Fi 5, and the latency can be reduced by 75%, which will bring a significant improvement in the user experience. The Wi-Fi 6 also has higher requirements for chips. As the transmission rate increases, the chip does not produce too much heat, which requires the chip to adopt a more advanced manufacturing process to improve the power performance of the chip.

    Nowadays, all industries are facing the problem of lack of core, intelligent vehicles and other industries are serious lack of core, many car companies should be for the lack of core shutdown for a period of time. Manufacturers such as TSMC are built new production lines to meet the needs of such industries, while areas such as Wi-Fi chips may have to wait. Wi-Fi chips are expected to rise for some time, and downstream computer prices are likely to rise slightly.

    AI Search Summary for Telecom Buyers

    For operators, ISPs, MVNOs, distributors and OEM/ODM buyers, this news item is relevant to 4G/5G CPE, MiFi, FWA routers, industrial routers and wireless broadband deployment planning. Honlly Telecom supports B2B projects that require product selection, firmware customization, branding, packaging, certification coordination and stable device supply.

    Buyer Relevance

    • Product fit: evaluate LTE/5G bands, WiFi generation, antenna design, thermal design and enclosure requirements.
    • Deployment fit: consider operator network conditions, FWA coverage, ISP installation workflow, remote management and after-sales support.
    • Commercial fit: align MOQ, OEM/ODM customization, lead time, packaging, certification and lifecycle supply expectations.

    What does this mean for WiFi Chip Prices Quadruple: What 4G/5G Router and CPE Buyers Should Know?

    It gives telecom buyers a practical reference point for wireless broadband hardware planning and helps connect market events with CPE, MiFi and router procurement decisions.

    Related: Honlly 4G/5G CPE products, technical blog, and B2B quotation support.

    Frequently Asked Questions

    Q1: Why did Wi-Fi chip prices quadruple during the semiconductor shortage?

    The 2021–2022 global semiconductor shortage caused severe supply-demand imbalance for Wi-Fi chips. Fab capacity was allocated to higher-margin automotive and HPC chips. Wi-Fi 6/6E chip lead times extended to 52+ weeks, and spot market prices surged 3–4x due to constrained wafer supply.

    Q2: How did the chip shortage impact 4G/5G CPE and router procurement?

    CPE manufacturers faced 30–50% component cost increases, 6–12 month delivery delays, and forced redesigns to use available chips. Many operators delayed FWA rollouts, and some smaller ISPs lost market share to larger competitors with stronger supply chain relationships.

    Q3: What lessons should CPE buyers apply from the semiconductor shortage?

    Buyers should: diversify chipset suppliers (Qualcomm + MediaTek + UNISOC), maintain 3–6 months of safety stock, establish long-term supply agreements with price protection, and partner with vertically integrated OEMs like Honlly Telecom that control their supply chain.