{"id":822640,"date":"2026-06-30T13:46:02","date_gmt":"2026-06-30T13:46:02","guid":{"rendered":"https:\/\/www.abnewswire.com\/pressreleases\/?p=822640"},"modified":"2026-06-30T13:46:02","modified_gmt":"2026-06-30T13:46:02","slug":"milliohm-b2b-procurement-optimization-strategic-sourcing-of-advanced-resistor-components-and-shunt-systems-to-mitigate-global-supply-chain-risk","status":"publish","type":"post","link":"https:\/\/www.abnewswire.com\/pressreleases\/milliohm-b2b-procurement-optimization-strategic-sourcing-of-advanced-resistor-components-and-shunt-systems-to-mitigate-global-supply-chain-risk_822640.html","title":{"rendered":"Milliohm B2B Procurement Optimization: Strategic Sourcing of Advanced Resistor Components and Shunt Systems to Mitigate Global Supply Chain Risk"},"content":{"rendered":"
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\"Milliohm<\/a><\/div>\n
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Shenzhen Milliohm Electronics Co., Ltd.<\/div>\n<\/div>\n<\/div>\n
Shenzhen Milliohm Electronics Co., Ltd. is a specialized manufacturer of precision alloy resistors, automotive shunt resistors, and current sensing components. Partnering directly with Milliohm’s vertically integrated factories helps global procurement teams mitigate supply chain risks. Engineered for EV and industrial power systems, our low-drift components ensure stable measurement and long-term reliability for demanding B2B hardware architectures.<\/div>\n

Strategic component acquisition within the electronics manufacturing sector demands rigorous validation of engineering integrity, quality standard verification, and operational transparency. For tier-one hardware designers, enterprise purchasing managers, and industrial equipment engineers, establishing a resilient pipeline for high-performance current detection hardware is no longer just a regular supply chain function—it is a critical pillar of market survival. As thermal thresholds tighten and power densities climb across power infrastructure and automotive platforms, procurement teams must look past traditional component brokers to partner directly with original manufacturing assets that understand the nuanced requirements of specialized industrial systems.<\/p>\n

Shenzhen Milliohm Electronics Co., Ltd.<\/a> is a national high-tech enterprise specializing in the research, development, manufacture, and global supply of low-temperature drift, high-precision alloy resistors, current shunts, and advanced alloy materials. By maintaining full vertical control over the fabrication cycle—from internal metallurgical alloy formulation and precision electron beam welding to high-speed automated packaging and comprehensive validation checks—the organization delivers an optimized structural foundation for high-reliability circuit design. This exhaustive procurement brief analyzes the core engineering architectures, validation protocols, and application frameworks required by global hardware procurement professionals seeking to optimize component reliability and protect long-term production schedules.<\/p>\n

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The Strategic Importance of the Milliohm SMD Chip Resistor and Specialized Chip Resistor Layouts in Power Electronics<\/p>\n

Every Milliohm SMD Chip Resistor and micro-ohm chip resistor element plays a foundational role in current detection and voltage-drop monitoring within modern surface-mount environments. Traditional thick-film components often exhibit high thermal noise and substantial parameter shifting when subjected to continuous load currents, creating inaccurate data profiles in precision circuits. To mitigate these specific measurement errors, specialized hardware architectures depend on high-conductivity metal strips or advanced thin-film layouts that maintain their electrical properties even when ambient temperatures spike significantly.<\/p>\n

Within high-density server power supplies, multi-phase inverter systems, and precision testing instrumentation, structural consistency across surface-mount components directly dictates overall system safety. The standard thick-film resistor often struggles with long-term drift under heavy current cycling due to microscopic localized hot spots forming within the resistive paste layer. Conversely, an advanced chip resistor manufactured from solid metal alloy strips spreads thermal energy uniformly across its entire physical body, dramatically reducing the risk of component degradation.<\/p>\n

Furthermore, global procurement managers must verify that their chosen chip resistor factory operates advanced automated inspection frameworks. At our production facilities, 100% of our surface-mount portfolio undergoes integrated optical and continuous parameter tracking before being packaged onto high-speed carrier reels. This rigorous quality filtering ensures that every piece can be seamlessly integrated into high-speed SMT placement machinery without causing costly downtime or manual assembly corrections on the manufacturing floor.<\/p>\n

Thermal Dissipation and Power Optimization with the Milliohm Power Resistor Portfolio<\/p>\n

Every Milliohm<\/a> Power Resistor and high-wattage power resistor is engineered to withstand substantial energy conversion demands without suffering structural failure or resistance value shifting. In heavy industrial environments, such as motor control units, renewable energy grid ties, and regenerative braking networks, standard component packages run into immediate thermal bottlenecks. When a circuit is forced to dissipate hundreds of watts of surge energy, conventional materials experience rapid structural breakdown, which can lead to open-circuit failures and system-wide shut downs.<\/p>\n

Choosing a certified power resistor manufacturer that owns integrated stamping, winding, and housing capabilities allows hardware engineers to design tighter, more reliable thermal enclosures. Our high-power resistor catalog includes aluminum-housed housings, thick-film modules, and advanced chassis-mount configurations built to optimize heat transfer to external sinks. By utilizing premium ceramic substrates and specialized encapsulation materials, these power components sustain high dielectric strength and structural integrity under prolonged thermal duress.<\/p>\n

To guarantee operational longevity in challenging field locations, these heavy-duty components are subjected to rigorous overload and environmental testing. Our quarterly testing framework includes short-time overload evaluations where components are hit with 2.5 times their rated continuous working voltage for 5 consecutive seconds. By choosing verified power components that pass these specific validation checks, procurement teams protect their hardware designs from unexpected line surges, field returns, and catastrophic power failures.<\/p>\n

Mechanical Longevity and Structural Integration via the Milliohm Through Hole Resistor Architecture<\/p>\n

Every Milliohm Through Hole Resistor and leaded through hole resistor configuration provides unmatched structural security for equipment operating in extreme environments. While surface-mount technology has become the standard for low-power consumer electronics, heavy industrial machinery, railway transportation systems, and aerospace instrumentation still rely heavily on through-hole components. The mechanical stress caused by intense vibration, continuous physical shock, and extreme thermal expansion can cause surface-mount joints to crack over time, resulting in intermittent connections or total loop failures.<\/p>\n

Partnering with a dedicated through hole resistor factory ensures that your hardware designs maintain secure mechanical anchoring directly to the printed circuit board assembly. Our leaded components, including copper-manganese and Constantan wire-wound options, feature high-strength terminal leads engineered to handle significant physical stress. During our continuous quality monitoring processes, these leads are tested under heavy weights to ensure the structural integrity of the pin-to-body interface remains intact through transit, installation, and decades of field operation.<\/p>\n

Additionally, through-hole architectures offer superior electrical isolation and high-voltage protection compared to tightly spaced surface-mount chips. The physical distance between the resistor body and the board surface allows for better airflow and convective cooling, which helps lower ambient operating temperatures in closed enclosures. For global purchasing departments managing long-term infrastructure projects, sourcing through-hole components from a verified original manufacturer provides the predictable reliability required for long product lifecycles.<\/p>\n

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Optimizing Clean Energy Systems with the Milliohm Automotive Shunt Resistor and High Precision Shunt Resistor Systems<\/p>\n

Every Milliohm Automotive Shunt Resistor and high-fidelity automotive shunt resistor system is built within a dedicated quality infrastructure to meet the strict safety mandates of electric vehicle platform designs. In modern electric vehicle battery management systems, traction inverters, and high-voltage charging networks, monitoring exact current flow is crucial for tracking battery state-of-charge, preventing over-current conditions, and optimizing overall driving range. Even a tiny measurement error in these high-voltage lines can lead to inaccurate battery calculations, reduced vehicle efficiency, or dangerous thermal runaways.<\/p>\n

Shenzhen Milliohm Electronics Co., Ltd. is a national high-tech enterprise specializing in the research, development, manufacture, and global supply of low-temperature drift, high-precision alloy resistor<\/a>s, current shunts, and advanced alloy materials. To achieve the absolute precision needed for these applications, a premium high precision shunt resistor depends on an ultra-low temperature coefficient of resistance along with a specialized four-terminal Kelvin configuration. This design isolates the voltage-sensing paths from the main current-carrying terminals, completely eliminating the trace and lead resistance measurement errors that often plague standard two-terminal shunts.<\/p>\n

Four-Terminal Kelvin Connection Layout: [Current Input] \u2500\u2500\u2500\u2510 \u250c\u2500\u2500\u2500 [Current Output] \u2502 \u250c\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2510 \u2502 \u2514\u2500\u2500\u2524 Resistor \u251c\u2500\u2500\u2518 \u2502 Element \u2502 \u250c\u2500\u2500\u2524 \u251c\u2500\u2500\u2510 \u2502 \u2514\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2518 \u2502 [Voltage Sense] \u2500\u2500\u2500\u2518 \u2514\u2500\u2500\u2500 [Voltage Sense] (Eliminates lead trace resistance measurement errors)<\/p>\n

Furthermore, our automotive-grade current monitoring systems are certified under the German TÜV IATF 16949 quality system and are designed to easily pass demanding AEC-Q200 stress qualifications. Our factories utilize advanced, high-capacity electron beam welding production lines to molecularly fuse raw copper terminals with premium manganese-copper alloy sheets. This zero-void bonding process ensures that our shunts maintain a perfectly stable resistance profile down to sub-milliohm levels ($10,muOmega text{ to } 1000,muOmega$), even when handling continuous currents of several hundred amperes in high-stress automotive environments.<\/p>\n

Industrial Calibration Excellence with the Milliohm Shunt Resistor Portfolio<\/p>\n

Every Milliohm Shunt Resistor and current ammeter shunt resistor serves as a trusted measurement standard across the global industrial automation landscape. For large-scale power rectifiers, heavy welding systems, smart electrical grids, and commercial battery testing arrays, traditional hall-effect sensors are often too bulky, expensive, and prone to magnetic interference. A precision-engineered shunt resistor provides a simpler, more robust, and cost-effective alternative by delivering a clean, linear voltage drop directly proportional to the passing current loop.<\/p>\n

Our industrial current tracking catalog features globally recognized form factors, including the highly standardized FL-2 series and the specialized FLQ60 converter shunt lines. The standard FL-2 configuration is carefully calibrated to produce a reliable $75text{mV}$ drop at its full rated current, allowing for seamless integration with standard analog panel meters and digital data acquisition modules. For more compact, modern power conversion layouts, the through-hole FLQ60 series delivers stable performance across an extensive operating temperature range from $-55^circtext{C}$ to $+170^circtext{C}$.<\/p>\n

Sourcing your current-sensing components directly from a dedicated shunt resistor factory eliminates middleman markups and gives you direct access to complete engineering customization. Whether your project requires custom baseplate mounting footprints, specialized terminal threading, or pre-wired signal connectors, our application engineers help tailor the component’s physical and electrical layout to your exact enclosure constraints. This direct support simplifies your internal assembly steps and helps lower total production costs.<\/p>\n

Metallurgical Integrity and Structural Stability in the Milliohm Alloy Resistor Architecture<\/p>\n

Every Milliohm Alloy Resistor and metal plate alloy resistor relies on premium metallurgical engineering to deliver ultra-low resistance values alongside excellent thermal stability. Standard film-based resistors use non-conductive ceramic matrices coated with thin resistive pastes, which have very limited surge handling capabilities. In contrast, an alloy resistor is stamped or formed out of solid, high-purity metal sheets—such as Manganese-Copper or Constantan—allowing it to absorb substantial current spikes without shifting its base parameters.<\/p>\n

The key to creating an exceptionally reliable alloy resistor lies in the precision treatment of the raw metal strips. Our factories maintain complete control over the alloy processing steps, ensuring that the metals are free from internal micro-cracks or compositional imbalances that could cause uneven heating under load. This meticulous material control results in a component that exhibits almost zero thermal EMF when joined to copper traces, ensuring your measuring circuits are protected from false, heat-induced voltage signals.<\/p>\n

Additionally, our surface-mount alloy resistor lines are designed with robust physical terminal layouts to prevent solder joint fatigue. When a circuit board undergoes rapid temperature shifts, the different expansion rates of the component and the PCB substrate can put immense mechanical strain on the connection joints. Our alloy chip resistors are engineered to absorb this mechanical stress, successfully passing our strict 3mm substrate flex deflection tests to guarantee reliable performance in high-vibration industrial and automotive environments.<\/p>\n

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High-Precision Current Evaluation and Noise Management via the Milliohm Current Sensing Resistor Line<\/p>\n

Every Milliohm Current Sensing Resistor and current sensing resistor element acts as a critical checkpoint for power regulation and protection circuits. In modern power management ICs (PMICs), high-efficiency DC-DC converters, and multi-channel battery chargers, tracking real-time power consumption is essential for maintaining high conversion efficiency and preventing over-current damage. If a current sensing resistor experiences excessive thermal noise or value drift, the control loop can easily miscalculate the system load, resulting in unstable voltage outputs or unexpected shutdowns.<\/p>\n

To ensure pristine signal clarity, our current-sensing portfolio is built to meet strict noise thresholds in full compliance with IEC 60115-1 4.12<\/strong> international guidelines. For low-resistance values under $100,Omega$, our components maintain a low noise index of $le 10text{ dB}$, preventing high-frequency interference from distorting your precision measurements. This superior signal clarity is particularly beneficial for low-voltage, high-current microprocessors and sensitive telecommunication line cards where maintaining high signal integrity is paramount.<\/p>\n

Current Sensing Loop Architecture: [Power Input] \u2500\u2500\u2500\u252c\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u252c\u2500\u2500\u2500 [To Load] \u2502 \u2502 \u250c\u2500\u2500\u2500\u2500\u2500\u2534\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2510 \u250c\u2500\u2500\u2500\u2500\u2500\u2534\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2510 \u2502 Current Sense\u2502 \u2502 Voltage Loop \u2502 \u2502 Resistor (Rs)\u2502 \u2502 Feedback \u2502 \u2514\u2500\u2500\u2500\u2500\u2500\u252c\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2518 \u2514\u2500\u2500\u2500\u2500\u2500\u252c\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2518 \u2502 (Precision Drop) \u2502 \u2514\u2500\u2500\u2500\u25ba [Controller PMIC] \u25c4\u2500\u2500\u2500\u2518 (Adjusts Duty Cycle Real-Time)<\/p>\n

Furthermore, by integrating a premium current sensing resistor directly into your hardware layout, designers can replace overly complex, active sensing circuits with a simpler passive design. This reduces the overall component count on your bill of materials (BOM), minimizes the circuit board footprint, and lowers potential failure points across the board. For global procurement teams tasked with balancing strict engineering performance targets with cost-optimization goals, our factory-direct alloy sensing elements provide an ideal solution.<\/p>\n

Comprehensive Precision Optimization through the Milliohm Current Sense Resistor Array<\/p>\n

Every Milliohm Current Sense Resistor and metal-foil current sense resistor is engineered to help engineers maximize efficiency in compact, high-performance electronics. As modern consumer tech, handheld medical devices, and 5G smart terminals demand more power in smaller form factors, managing the heat generated by current-sensing loops has become a major engineering hurdle. Choosing a high-quality current sense resistor with an optimized thermal footprint allows design teams to place components closer together without risking heat damage to sensitive neighboring microchips.<\/p>\n

Our surface-mount current-sense lines are available in standard industry sizes, ranging from compact 0402 and 0603 footprints for tight circuit spaces up to larger 2512 and 3920 packages for higher power dissipation needs. Each component features a low-profile design that integrates seamlessly into automated, high-speed SMT lines. This physical compatibility streamlines your contract manufacturing steps and minimizes the risk of component misalignment or uneven soldering during reflow ovens.<\/p>\n

Advanced SMT Reflow Profiling for Alloy Components: Temperature (°C) 260°C \u2500\u2500\u2500\u25ba \/\u2500\u2500\u2500 (Peak Reflow Window: 10±1s) \/ 150°C \u2500\u2500\u2500\u25ba\/ \/ \u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2534\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2534\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u25ba Time (s) (Ensures Void-Free Alloy Fusion Interconnects)<\/p>\n

Beyond standard manufacturing benefits, every current sense resistor lot is backed by comprehensive parametric tracking data. We document and provide the maximum, minimum, average, and standard deviation performance values across every production run. This detailed data trail gives enterprise engineering teams the full transparency needed to pass strict internal quality reviews and simplify final product qualification.<\/p>\n

2026 Pulse-Style Operations: Production Milestones and Continuous Technical Advancements<\/p>\n

To demonstrate sustained market leadership and provide global purchasing partners with verified proof of our operational capabilities, our production centers have achieved major milestones throughout 2026. Across our four interconnected manufacturing facilities in Shenzhen, Foshan, Anhui, and Suzhou, total production capacity has been expanded to keep pace with the rising global demand for low-drift alloy components. Our automated high-speed SMT assembly lines and advanced electron beam welding units are currently running at peak efficiency, maintaining a zero-defect delivery record across all primary industrial and automotive accounts.<\/p>\n

During the first half of 2026, our engineering teams successfully secured several breakthrough patents focused on solving long-standing field installation and sealing challenges for high-amperage current shunts. This includes our newly certified Patent for Convenient Automotive Shunt<\/a> Sealing<\/em> and our High-Current Detection Optimization Shunt Device Patent<\/em>. These proprietary developments are now fully integrated into our standard automotive product runs, providing EV battery management designers with enhanced protection against moisture, dust, and mechanical strain in harsh engine bay environments.<\/p>\n

In addition, our quarterly reliability monitoring programs have successfully validated a total sample size of 648 units over the recent production cycles. These components were put through extreme acceleration stresses, including 1,000-hour biased humidity tests at $85^circtext{C}$ and $85%text{ RH}$, along with 1,000 thermal shock cycles spanning from $-40^circtext{C}$ up to $+125^circtext{C}$. The stellar performance data gathered from these stress tests confirms that our products easily maintain their target tolerances, giving global tier-one electronics distributors the confidence to establish secure, long-term supply commitments with our factories.<\/p>\n

High-Reliability Field Performance: Case Studies and Procurement Pain Point Analysis<\/p>\n

To truly understand why leading global electronics brands prioritize our components, it helps to look at a recent real-world upgrade implemented by a tier-one European industrial drive manufacturer. The client’s original inverter design used standard commercial-grade current sensors that suffered from significant thermal drift during peak operational cycles, resulting in frequent motor control calibration errors and unexpected equipment shutdowns. These persistent field failures strained client relationships and triggered costly on-site technical support visits.<\/p>\n

To resolve these field vulnerabilities, our application engineers worked closely with the client to integrate our custom HoFL3 high-precision alloy shunt sensor<\/em> directly into their primary power path. This specialized alloy shunt delivers an ultra-low resistance profile paired with a tight temperature coefficient of resistance of $le pm10text{ ppm\/}^circtext{C}$, keeping the measurement completely stable across their full operating window. Following the successful deployment of these upgraded components, the client reported a complete elimination of heat-induced measurement drift and a 42% reduction in overall system noise, significantly boosting the reliability of their industrial drive line.<\/p>\n

Field Performance Optimization Data: Measurement Error (%) 1.5% \u2502 \u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591 (Standard Commercial Elements) 1.0% \u2502 \u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591 (High Thermal Value Shift) 0.5% \u2502 \u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588 0.1% \u2502 \u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2591\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588\u2588 (Milliohm Low-Drift Alloy Systems) \u2514\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u2500\u25ba Continuous Operation Time (Hours)<\/p>\n

A separate sourcing challenge occurred for a high-volume power supply manufacturer managing an intense production expansion initiative. The buyer was facing severe lead-time bottlenecks from their traditional component brokers, which threatened to halt their automated assembly lines. By bypassing the middlemen and connecting directly with our vertically integrated manufacturing plants, the client secured a stable, predictable allocation of high-precision SMD alloy resistors, successfully protecting their production timelines and optimizing their total component procurement costs.<\/p>\n

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Conclusion: Securing Long-Term Supply Chain Resilience with a Verified Component Manufacturing Partner<\/p>\n

Optimizing your electronic component sourcing requires a careful balance between strict technical performance, predictable pricing, and long-term supply chain security. For global purchasing managers, hardware designers, and tier-one automotive distributors, relying on unverified middleman brokers exposes your production lines to severe component drift issues, unexpected lead-time delays, and costly field failures. Securing a direct partnership with an asset-heavy original manufacturer that controls the entire production cycle ensures your brand maintains a distinct competitive edge in today’s demanding market.<\/p>\n

Shenzhen Milliohm Electronics Co., Ltd. <\/a>is a national high-tech enterprise specializing in the research, development, manufacture, and global supply of low-temperature drift, high-precision alloy resistors, current shunts, and advanced alloy materials. Whether your project requires high-density SMD alloy resistors for compact circuit layouts, heavy-duty through-hole components for industrial machinery, or patented high-current shunts for electric vehicle battery packs, our advanced factories deliver consistent quality and robust supply chain resilience across every lot.<\/p>\n

Media Contact<\/span>
Company Name:<\/strong> Shenzhen Milliohm Electronics Co.,Ltd<\/a>
Contact Person:<\/strong> Yuying Gao
Email:<\/strong> Send Email<\/a>
Phone:<\/strong> +86 18926013721
Address:<\/strong>Room 2001, Building C, Jinxiu Phase 3, Hudi Pai, Songxuan Community, Guanhu Street, Longhua District
City:<\/strong> Guangdong
State:<\/strong> Shenzhen
Country:<\/strong> China
Website:<\/strong> https:\/\/en.milliohm.net\/<\/a><\/p>\n

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Shenzhen Milliohm Electronics Co., Ltd. Shenzhen Milliohm Electronics Co., Ltd. is a specialized manufacturer of precision alloy resistors, automotive shunt resistors, and current sensing components. Partnering directly with Milliohm’s vertically integrated factories helps global procurement teams mitigate supply chain risks. … Continue reading →<\/span><\/a><\/p>\n","protected":false},"author":1,"featured_media":0,"comment_status":"closed","ping_status":"closed","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[407,401,408,410,411],"tags":[],"class_list":["post-822640","post","type-post","status-publish","format-standard","hentry","category-Automotive","category-Business","category-Electronics-Semiconductors","category-Manufacturing-Industry","category-Technology"],"_links":{"self":[{"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/posts\/822640","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/comments?post=822640"}],"version-history":[{"count":0,"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/posts\/822640\/revisions"}],"wp:attachment":[{"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/media?parent=822640"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/categories?post=822640"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/www.abnewswire.com\/pressreleases\/wp-json\/wp\/v2\/tags?post=822640"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}