Analyseur de réseau vectoriel (VNA) OMICRON Lab Bode 500
Analyseur de réseau vectoriel (VNA) OMICRON Lab Bode 500
Key Features:
- Idéal pour tester et développer des SMPS
- Convient à la caractérisation des composants.
Présentation du Bode 500 : révolutionnez votre expérience de test
Êtes-vous prêt à élever vos capacités de test au niveau supérieur ? Ne cherchez pas plus loin que le Bode 500, la dernière innovation d'OMICRON Lab. Avec ses fonctionnalités remarquables et ses avantages inégalés, ce puissant analyseur est sur le point de transformer la façon dont vous effectuez vos mesures.
Gamme de fréquences inégalée
Le Bode 500 dispose d'une plage de fréquences ultra-large, permettant des mesures précises de < 1 Hz jusqu'à 450 MHz. Dites adieu aux limitations et bonjour à une précision sans précédent.
La précision à son meilleur
Bénéficiez d'une linéarité élevée et d'une plage dynamique exceptionnelle de plus de 120 dB, ce qui rend l'analyse du réseau vectoriel, l'analyse de la réponse en fréquence et les mesures d'impédance incroyablement précises. Basculez entre une terminaison de 50 Ω et une impédance élevée (1 MΩ avec couplage CA) pour des mesures polyvalentes sur les systèmes actifs et les sondes externes.
Puissance et performance
Avec une plage dynamique de 56 dB en sortie et un niveau de puissance maximal de 16 dBm, le Bode 500 fournit une puissance d'injection de signal suffisante. Parfait pour les mesures de gain de boucle et d'impédance de sortie sur les convertisseurs à découpage et les réseaux de distribution d'énergie (PDN). C'est le choix ultime pour les vérifications d'intégrité de l'alimentation et les évaluations de stabilité de boucle.
Polyvalent et portable
Le Bode 500 est non seulement puissant, mais aussi incroyablement pratique. C'est un instrument portable, silencieux et sans ventilateur qui peut être alimenté via Ethernet (PoE), USB (USB-PD) ou une alimentation standard. Ses interfaces USB-C et Ethernet assurent une connectivité transparente à votre réseau ou à votre ordinateur de contrôle.
Expérience utilisateur fluide
Associé à la suite Bode Analyzer, le Bode 500 offre la même expérience conviviale que le bien-aimé Bode 100. De plus, il peut être contrôlé directement via des commandes SCPI, permettant des mesures automatisées autonomes et indépendantes de la plate-forme.
Prêt à révolutionner votre expérience de test ? Ne manquez pas l'opportunité de porter vos mesures à de nouveaux sommets avec le Bode 500. Enregistrez votre intérêt dès aujourd'hui et entrez dans une nouvelle ère de précision et d'efficacité. Votre réussite commence ici.
Frequency Response Analyzer - Bode 100
The Bode 100 is the professional solution to perform accurate and fast frequency sweep measurements from 1 Hz to 50 MHz, essential for power supply design and stable loop operation. The dedicated hardware offers fast sweep performance together with unsurpassed noise rejection allowing high-dynamic range measurements not only on passive components and linear regulators but also on switching converters. Together with the Bode Analyzer Suite the Bode 100 is the perfect choice to equip your design lab. It enables you to analyze systems, control loops, electronic components and much more at a great price-performance ratio. The Bode 100 does not only offer frequency response analysis (FRA) but also vector network analysis (VNA) & impedance analyzer capabilities. Equip yourself and become a happy Bode-User! |
Power Electronics Design & Analysis
Measuring a transfer function via frequency response analysis is a powerful method for the design of electronic systems such as compensators for switching converters or voltage regulators. The Bode 100 hardware and software are optimized for loop and impedance measurements, stability analysis and much more. Have a look at the following main applications in power electronics to find out how the Bode 100 can support you in your design process:
Loop Gain (Phase Margin & Gain Margin)
One of the most important steps when characterising or designing the control loop for a power converter. The Bode 100 offers high side-band rejection and a high dynamic range at an unbeatable measurement speed. Perform loop-response measurements within seconds to fully characterise your control loop at various operating points and conditions. Check out how quick and simple stability measurements can be and have a look at our Application Note. |
Companion Power Supply Design Software for Bode 100
Working in perfect harmony with Biricha's WDS automated power supply design software, Bode 100 helps to greatly reduce the development time and cost of your power supplies. Use WDS to design stable analog and digitally controlled power supplies in minutes!
The WDS power supply design software from Biricha simplifies power supply design and includes automatic pole-zero placement for optimum compensation. Besides the included topologies such as Buck, Boost, Buck-Boost, Flyback, SEPIC, Full bridge, Half bridge and forward converters, WDS now features the possibility to import a measured plant transfer function from the Bode 100 to design a stable compensator. Check out this webinar from Dr. Ali Shirsavar to learn more about this simple and innovative solution.
Output Impedance (Non-Invasive Stability Measurement)
The output impedance plot contains information about the stability of the feedback loop as well as information about the decoupling network. Use the NISM (Non-Invasive Stability Measurement) method to derive the phase margin from a single output impedance measurement. Check out this Application Note to learn how to perform this simple and fast measurement. Check out the Picotest accessories for simplified power integrity measurements. |
The negative input resistance of a DC/DC converter can lead to oscillations when using an undamped input filter. The Bode 100 provides the possibility to check the input impedance of the converter as well as the impedance spectrum of the filter that could lead to instability problems at resonance. Check out the Application Note on input filter stability to find out more. |
The impedance plot of electronic components provide a deep insight into the AC properties such as capacitor ESR, transformer leakage, AC resistance of windings, self-resonance frequency of inductors and transformers, inductance of shunt-resistors, winding capacitance of transformers etc. Use the Bode 100 to perform fast and accurate impedance measurements from 1 Hz to 50 MHz. Check out our webinar to learn more about the power of the Bode 100 when used as an impedance analyzer. |
Power Supply Rejection Ratio (PSRR)
The power supply rejection ratio, also known as power supply ripple rejection, provides information on how well line-disturbances are rejected at the output. This information is especially useful for low-noise supplies and linear regulators. Check out this Application Note to learn how to perform a PSRR measurement. |
Analyseur de réseau vectoriel (VNA) OMICRON Lab Bode 500
Frequently Asked Questions
Ask a Question-
Is it possible to get a trial or demo of the Bode 500 VNA?
Yes, it is possible to arrange a trial of the Bode-500. The first production units for demonstrations and sale will be available in November and we can arange this then.
John Legg -
What is the warranty for the Bode-100?
The Bode-100 comes with a 2-year warranty.
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Is the Bode-100 compatible with any software?
The Bode-100 is compatible with Omicron-Lab's Bode-Analyzer software, which allows for easy data analysis and visualization.
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What is the maximum measurement speed of the Bode-100?
The Bode-100 has a measurement speed of up to 10 measurements per second.
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What is the frequency range of the Bode-100?
The Bode-100 has a frequency range of 1Hz to 50MHz.
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What types of measurements can the Bode-100 perform?
The Bode-100 can perform a wide range of measurements, including small-signal stability, input and output impedance, gain and phase margin, power factor, total harmonic distortion, and conducted and radiated emissions.
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What is the Omicron-Lab Bode-100?
The Omicron-Lab Bode-100 is a vector network analyzer (VNA) designed for small-signal stability and frequency-domain analysis of electronic circuits.