What is the Rogers 4350B High Frequency Circuit Materials?
Rogers 4350B PCB Supplier. We have made the Rogers 4350B core pcb boards from 2 couche à 30 couches. We offer ultrathin Rogers 4350B PCB, Blind & buried vias Rogers 4350B pcb, Mixed medium HDI Rogers 4350B PCBS.
Nous achetons ces matériaux auprès d'un agent de Rogers Materials, puis traitons et produisons des circuits imprimés vierges.. Nous ne produisons pas de matériaux de base. Les informations suivantes sont uniquement à titre de référence.
Ro4003™ laminates are currently offered in various confifi gurations utilizing both 1080 et 1674 styles de tissu de verre, with all confifi gurations meeting the same laminate electrical performance specififi cation.
as a drop-in replacement for the RO4003C™ matériel, RO4350B™ laminates utilize RoHS compliant flfl ame-retardant technology for applications requiring UL 94V-0 certififi cation. Ces matériaux sont conformes aux exigences de l'IPC- 4103, feuille de barre oblique /10 pour RO4003C et /11 pour les matériaux RO4350B.
| Propriété | Valeur typique RO4003C RO4350B | Direction | Unités | Condition | Méthode d'essai | |
| Constante diélectrique, est Processus | 3.38 ± 0.05 | (2)3.48 ± 0.05 | Z | — | 10 GHz/23°C | IPC-TM-650 2.5.5.5 Stripline serrée |
| (1) Constante diélectrique, est Conception | 3.55 | 3.66 | Z | — | 8 à 40 Ghz | Méthode de longueur de phase différentielle |
| Facteur de dissipation bronzage, d | 0.0027 0.0021 | 0.0037 0.0031 | Z | — | 10 GHz/23°C 2.5 GHz/23°C | IPC-TM-650 2.5.5.5 |
| Coefficient thermique de er | +40 | +50 | Z | ppm/°C | -50°C à 150°C | IPC-TM-650 2.5.5.5 |
| Résistivité volumique | 1.7 X 1010 | 1.2 X 1010 | MΩ•cm | COND A | IPC-TM-650 2.5.17.1 | |
| Résistivité superficielle | 4.2 X 109 | 5.7 X 109 | MΩ | COND A | IPC-TM-650 2.5.17.1 | |
| Force électrique | 31.2 (780) | 31.2 (780) | Z | KV/mm (V/mil) | 0.51MM (0.020") | IPC-TM-650 2.5.6.2 |
| Module de traction | 19,650 (2,850) 19,450 (2,821) | 16,767 (2,432) 14,153, (2,053) | XY | MPa (ksi) | RT | ASTM D638 |
| Résistance à la traction | 139 (20.2) 100 (14.5) | 203 (29.5) 130 (18.9) | XY | MPa (ksi) | RT | ASTM D638 |
| Résistance à la flexion | 276 (40) | 255 (37) | MPa (kpsi) | IPC-TM-650 2.4.4 | ||
| Stabilité dimensionnelle | <0.3 | <0.5 | X,Y | mm/m (mils/pouce) | après gravure +E2/150°C | IPC-TM-650 2.4.39A |
| Coefficient de dilatation thermique | 11 14 46 | 10 12 32 | XYZ | ppm/°C | -55 à 288°C | IPC-TM-650 2.4.41 |
| Tg | >280 | >280 | °C DSC | UN | IPC-TM-650 2.4.24 | |
| TD | 425 | 390 | °C TGA | ASTM D3850 | ||
| Conductivité thermique | 0.71 | 0.69 | W/m/°K | 80° C | ASTM C518 | |
| Absorption d'humidité | 0.06 | 0.06 | % | 48 heures d'immersion 0.060" échantillon Température 50°C | ASTM D570 | |
| Densité | 1.79 | 1.86 | g/cm3 | 23° C | ASTM D792 | |
| Résistance au pelage du cuivre | 1.05 (6.0) | 0.88 (5.0) | N/mm (plus) | après le flotteur de soudure 1 oz. Feuille EDC | IPC-TM-650 2.4.8 | |
| Inflammabilité | N / A | (3)V-0 | UL 94 | |||
| Compatible avec les processus sans plomb | Oui | Oui | ||||
What is Rogers 4350b High frequency circuit boards?
High frequency PCB with Rogers material The increasing complexity of electronic components and switches continually requires faster signal flow rates, et donc des fréquences de transmission plus élevées. En raison des temps de montée des impulsions courts dans les composants électroniques, il est également devenu nécessaire pour les hautes fréquences (HF) technologie permettant de visualiser les largeurs de conducteurs en tant que composant électronique. En fonction de divers paramètres, Les signaux HF sont réfléchis sur le circuit imprimé, ce qui signifie que l'impédance (résistance dynamique) varie en fonction du composant d'envoi. Pour éviter de tels effets capacitifs, tous les paramètres doivent être exactement spécifiés, et mis en œuvre avec le plus haut niveau de contrôle des processus. La géométrie des traces de conducteurs est essentielle pour les impédances des cartes de circuits imprimés haute fréquence., l'accumulation de couches, et la constante diélectrique (εr) des matériaux utilisés.
ALCANTA PCB has bought these materials from an agent at Rogers Materials and then process and produce blank circuit boards.
PCB de Rogers
Matériaux utilisés pour les circuits imprimés HF:
Cartes haute fréquence, par exemple. pour les applications sans fil et les débits de données dans la plage supérieure des GHz ont des exigences particulières en matière de matériau utilisé: Permittivité adaptée Faible atténuation pour une transmission efficace du signal Construction homogène avec de faibles tolérances d'épaisseur d'isolation et de constante diélectrique Pour de nombreuses applications, it is sufficient to use FR4 material with an appropriate layer buildup. En outre, nous traitons des matériaux haute fréquence aux propriétés diélectriques améliorées. Ceux-ci ont un facteur de perte très faible, une faible constante diélectrique, et sont principalement indépendants de la température et de la fréquence. Des propriétés supplémentaires favorables sont une température de transition vitreuse élevée, une excellente durabilité thermique, et taux d'hydrophile très faible. Nous utilisons (entre autres) Matériaux Rogers ou PTFE (Par exemple, Téflon de DuPont) pour circuits imprimés haute fréquence à impédance contrôlée. Des compositions sandwich pour des combinaisons de matériaux sont également possibles.
Contrôle d'impédance: L'impédance définie par le client est testée par nos ingénieurs de la station CAM sur la fabricabilité. En fonction de la constitution des couches, la disposition du PCB et les impédances demandées par le client, un modèle de calcul est choisi. Le résultat est toute modification nécessaire de la construction de la couche et les ajustements nécessaires aux géométries des conducteurs concernés.. Après la fabrication de circuits imprimés haute fréquence, les impédances sont vérifiées (avec une précision allant jusqu'à 5%), et les résultats détaillés sont enregistrés exactement dans un protocole de test.
What is ultrathin Rogers 4350B PCB?
Exploring the World of Ultrathin Rogers 4350B PCBs:
In the realm of modern electronics, where miniaturization and high-performance are paramount, the demand for ultrathin printed circuit boards (PCBS) has surged. Among the myriad of materials available for PCB fabrication, Rogers 4350B has emerged as a top contender for applications requiring exceptional electrical performance and dimensional stability. Let’s delve into the world of ultrathin Rogers 4350B PCBs to understand their significance and applications.
Introduction to Rogers 4350B:
Rogers 4350B is a high-frequency laminate material renowned for its outstanding electrical properties, stabilité thermique, et résistance mécanique. Composed of woven fiberglass reinforced hydrocarbon/ceramic laminate, Rogers 4350B offers a low dielectric constant (Dk) and low loss tangent (Df), making it ideal for high-frequency applications such as microwave, RF, and millimeter-wave circuits.
Characteristics of Ultrathin Rogers 4350B PCBs:
Ultrathin Rogers 4350B PCBs exhibit several notable characteristics that make them highly desirable for various advanced electronic systems:
- Reduced Thickness: One of the defining features of ultrathin Rogers 4350B PCBs is their significantly reduced thickness compared to traditional PCBs. With thicknesses ranging from 0.1mm to 0.5mm or even thinner, these PCBs enable the development of sleek and compact electronic devices without compromising on performance.
- High Electrical Performance: Despite their thin profile, ultrathin Rogers 4350B PCBs maintain exceptional electrical performance, including low loss tangent and consistent dielectric properties across a wide range of frequencies. This ensures reliable signal transmission and minimal signal distortion, critical for high-frequency applications.
- Excellent Dimensional Stability: Rogers 4350B exhibits excellent dimensional stability, even at elevated temperatures, making it well-suited for applications requiring precise impedance control and tight tolerance requirements. This ensures consistent electrical performance and reliability over a wide range of operating conditions.
- Suitability for High-Frequency Applications: Ultrathin Rogers 4350B PCBs are specifically designed to meet the stringent requirements of high-frequency circuits, including microwave and RF applications. Their low dielectric constant and low loss tangent make them ideal for use in antennas, communications par satellite, systèmes radar, et équipement de réseau sans fil.
Applications of Ultrathin Rogers 4350B PCBs:
The versatility and high performance of ultrathin Rogers 4350B PCBs render them indispensable in a wide range of advanced electronic applications, including but not limited to:
- Wireless Communication Systems: Ultrathin Rogers 4350B PCBs are widely used in the development of wireless communication systems such as 5G infrastructure, Systèmes de communication par satellite, and high-speed data transmission equipment.
- Aerospace and Defense Electronics: Dans les applications aérospatiales et de défense, where reliability and performance are paramount, ultrathin Rogers 4350B PCBs are employed in radar systems, avionique, electronic warfare systems, and unmanned aerial vehicles (UAVs).
- Dispositifs médicaux: The compact size and high performance of ultrathin Rogers 4350B PCBs make them ideal for medical devices such as MRI machines, équipement à ultrasons, and implantable medical devices where space constraints and signal integrity are critical considerations.
- Électronique automobile: Dans l'industrie automobile, ultrathin Rogers 4350B PCBs find applications in advanced driver assistance systems (ADAS), vehicle-to-vehicle (V2V) systèmes de communication, and automotive radar systems for enhanced safety and connectivity.
Conclusion:
Ultrathin Rogers 4350B PCBs represent a significant technological advancement in the field of high-frequency electronics, offering unparalleled electrical performance, stabilité dimensionnelle, and versatility in a compact form factor. With their widespread applications across various industries, these ultrathin PCBs continue to drive innovation and enable the development of next-generation electronic systems with enhanced performance and reliability.
What is Microtrace Rogers 4350B PCB?
Exploring Microtrace Rogers 4350B PCB: Revolutionizing High-Frequency Circuitry:
Microtrace Rogers 4350B PCB represents a significant advancement in high-frequency circuitry technology, offering unparalleled performance and reliability in demanding applications. This innovative PCB material, developed by Rogers Corporation, combines the exceptional electrical properties of Rogers 4350B laminate with the precision of microtrace technology, ushering in a new era of miniaturization and high-frequency signal integrity.
En son coeur, Microtrace Rogers 4350B PCB is built upon Rogers 4350B laminate, a high-performance thermoset material renowned for its low dielectric constant (Dk) and low loss tangent (Df). These properties make Rogers 4350B an ideal substrate for high-frequency applications where signal integrity and minimal signal loss are paramount. By incorporating microtrace technology into Rogers 4350B laminate, Microtrace Rogers 4350B PCB achieves even greater precision and performance, making it a preferred choice for a wide range of industries including aerospace, télécommunications, et l'automobile.
Microtrace technology involves the precise fabrication of ultra-fine circuit traces and features on the PCB surface, allowing for higher circuit density and improved signal transmission. This technology enables designers to achieve smaller, plus léger, and more efficient electronic devices without compromising on performance. With Microtrace Rogers 4350B PCB, designers can create intricate circuitry with minimal line widths and spacing, pushing the boundaries of high-frequency design and enabling next-generation electronic systems.
One of the key benefits of Microtrace Rogers 4350B PCB is its ability to support miniaturization without sacrificing performance. By reducing the size of circuit traces and features, Microtrace technology allows for higher packing densities, enabling the integration of more functionality into smaller form factors. This is particularly advantageous in applications where space is limited, tels que les appareils mobiles, wearable electronics, and IoT sensors. Microtrace Rogers 4350B PCB empowers designers to create compact, léger, and energy-efficient products without compromising on functionality or reliability.
En outre, Microtrace Rogers 4350B PCB offers enhanced signal integrity and stability, thanks to the superior electrical properties of Rogers 4350B laminate. The low Dk and Df of Rogers 4350B ensure minimal signal loss and distortion, resulting in cleaner, more accurate signal transmission across high-frequency circuits. This is crucial for applications such as high-speed data communication, RF/microwave systems, et systèmes radar, where signal fidelity is critical for optimal performance.
In addition to its electrical properties, Microtrace Rogers 4350B PCB exhibits excellent mechanical and thermal stability, making it suitable for harsh operating environments. The robust construction of Rogers 4350B laminate provides exceptional resistance to moisture, produits chimiques, and temperature fluctuations, ensuring long-term reliability and durability in challenging conditions.
En conclusion, Microtrace Rogers 4350B PCB represents a groundbreaking advancement in high-frequency circuitry technology, combining the exceptional electrical properties of Rogers 4350B laminate with the precision of microtrace technology. By enabling miniaturization, améliorer l'intégrité du signal, and enhancing reliability, Microtrace Rogers 4350B PCB opens up new possibilities for high-frequency design and innovation across various industries. Comme la demande de plus petits, plus rapide, and more efficient electronic devices continues to grow, Microtrace Rogers 4350B PCB stands poised to lead the way towards a future of high-performance, miniaturized electronics.
What is Mixed medium Rogers PCB?
Mixed Medium Rogers PCB: Bridging the Gap Between High-Frequency and Conventional Circuitry
In the realm of printed circuit boards (PCBS), the demand for versatile solutions that can accommodate both high-frequency and conventional circuitry has led to the emergence of mixed medium Rogers PCBs. These innovative PCBs combine the high-performance characteristics of Rogers laminate materials with traditional FR-4 substrates, offering a balanced approach to meet the diverse needs of modern electronic designs.
En son coeur, mixed medium Rogers PCBs leverage the exceptional electrical properties of Rogers laminates, such as Rogers 4350B, which are renowned for their low dielectric constant (Dk) and low loss tangent (Df). These properties make Rogers laminates ideal for high-frequency applications, where signal integrity and minimal loss are critical. By incorporating Rogers laminate layers into the PCB stackup, mixed medium Rogers PCBs ensure superior high-frequency performance, enabling efficient signal transmission and reduced electromagnetic interference (EMI).
Cependant, mixed medium Rogers PCBs also integrate traditional FR-4 layers into their construction. FR-4 is a widely used substrate material known for its cost-effectiveness, résistance mécanique, and ease of fabrication. By combining Rogers laminates with FR-4 layers, mixed medium PCBs strike a balance between high-frequency performance and conventional circuitry requirements. This hybrid approach allows designers to integrate both high-frequency and low-frequency components onto a single PCB, reducing complexity and optimizing space utilization.
The construction of mixed medium Rogers PCBs involves careful consideration of layer stackup and material selection. Typiquement, the high-frequency signal layers utilize Rogers laminates, while the inner and outer layers for low-frequency components employ FR-4 material. This strategic layer arrangement ensures that high-frequency signals propagate efficiently through the Rogers layers, while low-frequency signals are adequately routed through the FR-4 layers.
One of the key advantages of mixed medium Rogers PCBs is their versatility. These PCBs can accommodate a wide range of applications, from high-speed data communication and RF/microwave systems to power electronics and control circuits. By providing a seamless transition between high-frequency and conventional circuitry, mixed medium Rogers PCBs offer designers the flexibility to optimize performance and cost according to specific project requirements.
En outre, mixed medium Rogers PCBs offer enhanced reliability and thermal performance. The combination of Rogers laminates with FR-4 layers results in improved thermal conductivity and heat dissipation, ensuring efficient operation even under high-power conditions. This is particularly beneficial for applications that require prolonged operation at elevated temperatures, such as automotive electronics and industrial controls.
En plus, mixed medium Rogers PCBs streamline the manufacturing process by eliminating the need for separate high-frequency and conventional PCBs. This reduces assembly time, coûts matériels, and potential points of failure, ultimately leading to faster time-to-market and lower overall production costs.
En conclusion, mixed medium Rogers PCBs represent a versatile and cost-effective solution for modern electronic designs that require a balance between high-frequency performance and conventional circuitry. By leveraging the unique characteristics of Rogers laminates and FR-4 substrates, these PCBs offer superior signal integrity, fiabilité, and thermal performance across a wide range of applications. As the demand for high-performance, multi-functional electronic devices continues to grow, mixed medium Rogers PCBs are poised to play a crucial role in enabling innovation and driving progress in the electronics industry.