Introduction

Greeting esteemed engineers, embarked on a comprehensive analysis of Yageo's CC1206MKX5R6BB476, a ceramic capacitor from the reputable manufacturer, we find ourselves on a quest to explore its performance characteristics in relation to a statistical benchmark formed from other capacitors of the same nominal value. This X5R ceramic capacitor stands up for scrutiny across multiple fascinating parameters, as we dig deep and provide an instructive and enlightening sensory reading experience.

Join us in our expedition to assess the CC1206MKX5R6BB476 47μF surface mount capacitor in a 1206 (3216 metric) package with a 10-volt rating and a generous tolerance of ±20%.

• Competitive capacitance response at higher frequencies
• Stable dissipation factor response at a wide frequency range
• High-quality factor at mid-range frequency

• Lower than average capacitance at low frequencies
• Anomalies in series resistance response at very high frequencies
• Poor quality factor values at highest frequency points

Marching forth incorporating various parameters extracted from the component's LCR measurements, at both 1 Volt and 10 Volts test frequencies, we debate the potential choice of this 47μF X5R capacitor, the CC1206MKX5R6BB476 for your engineering aspirations.

Impedance

In examining the impedance features of the Yageo CC1206MKX5R6BB476 capacitor, it is evident that the component demonstrates a distinct performance profile. When subjected to a test voltage of 1V, this multilayer ceramic capacitor (MLCC) exhibits an above-average impedance across a large portion of the frequency spectrum. For instance, at 10kHz, the capacitor registers an impedance of 508.1mΩ, a value considerably lower than the average value of 637.7mΩ observed in capacitors of the same category. Furthermore, at a frequency of 100kHz, the impedance provided by this component (53.3mΩ) is significantly below the benchmark average value of 319.4mΩ.

From the information supplied, one can deduce that the capacitor's performance becomes more consistent at higher test frequencies. Similar impedance trends are noticeable under a test voltage of 10V. At lower frequencies, such as 5Hz and 10Hz, the impedance values are marginally higher than their counterparts in the benchmark data, although they remain within acceptable limits.

However, it is important to highlight that when operating under varying test voltages, performance discrepancies become more pronounced. For example, at 500kHz, the impedance values slightly deviate from the benchmark statistics when tested at 1V (14.71mΩ) and 10V (5.19mΩ) conditions. This deviation imparts a unique performance identity to the Yageo CC1206MKX5R6BB476 capacitor. Impedance characteristics are critical to the capacitor's functionality in various applications, such as filtering and energy storage. As such, understanding the behavior of this component across different frequency ranges and test voltages is essential for selecting the appropriate use cases and optimizing circuit performance.

Capacitance

While examining the LCR measurements of the CC1206MKX5R6BB476 Capacitor at 1 Volt, it is evident that the capacitance maintains stability and is relatively close to the statistical benchmark averages in lower test frequencies. For instance, at 5Hz, the measured capacitance is 48.05μF, a slightly lower value than the average of 49.2μF. Similarly, at 10Hz, the capacitance is at 47.76μF in contrast to the average of 48.14μF. This trend persists until 100Hz, at which point a noticeable deviation from the benchmark becomes evident as the frequency continues to increase.

In the frequency range of 500Hz to 1kHz, the Capacitor exhibits a significant drop, falling to approximately 35.65μF and 33.82μF, respectively. This is in contrast to the benchmark averages of 41.55μF and 40.54μF. The discrepancy between measured capacitance and benchmark averages continues to widen as the frequency rises, reaching its peak at 600kHz with the Capacitor registering a surprising 139.2μF—substantially higher than the benchmark average of 79.05μF. Of note, Capacitor data at frequencies beyond 700kHz is unavailable. Nevertheless, the available data provide essential insights into the Capacitor's performance characteristics.

Upon examining the Capacitor at 10 Volts, the lower frequency measurements exhibit relative consistency, closely following the benchmark averages. It is worth highlighting a peculiar event at 50Hz where the Capacitor performs better at 31.64μF compared to a lower voltage reading of 44.73μF. Furthermore, within the frequency range of 150kHz to 300kHz, the Capacitor's capacitance maintains a steady fluctuation with only slight variations. Beyond 300kHz, there is a dramatic increase in capacitance, reaching an impressive value of 340.1μF at 500kHz, which significantly surpasses benchmark data.

To determine the appropriateness of the CC1206MKX5R6BB476 Capacitor for specific circuit applications, a thorough evaluation of its performance characteristics at various voltage levels and frequencies is necessary. Given its relatively consistent results within lower frequency ranges and the unexpectedly high capacitance observed in higher frequencies, particularly exceeding 300kHz, engineers must take this significant aspect into account when assessing the suitability of this Capacitor to their designs and applications.

Series Resistance

In this section, we meticulously assess the Yageo CC1206MKX5R6BB476 component's series resistance and compare its performance to the statistical benchmark data. Let us first examine the LCR measurements of the CC1206MKX5R6BB476 at 1 Volt, where it illustrates that the series resistance ranges from 38.46Ω at a lower test frequency of 5Hz to an impressively lower value of 14.04mΩ at a higher frequency of 1MHz. Such a comparison with the benchmark data clearly demonstrates that the capacitor performs substantially better than the average, especially at higher test frequencies, as evidenced by even lower series resistance values, such as 133.8mΩ at 1kHz, 20.94mΩ at 10kHz, and 14.55mΩ at 100kHz.

While assessing the component's performance at lower test frequencies, we notice that the Yageo CC1206MKX5R6BB476's series resistance deviates more from the benchmark but still exhibits admirable characteristics. To provide specific examples, it displays values of 4.557Ω at 50Hz and 2.364Ω at 100Hz.

Diving deeper into the analysis of CC1206MKX5R6BB476's LCR measurements at 10 Volts, we can uncover additional insights into its series resistance performance. With values ranging from 73.12Ω at 5Hz, 46.08Ω at 10Hz, and 7.962Ω at 50Hz, the component continues to maintain a similar positive trend as observed at lower voltage levels. More notably, it outperforms the benchmark at higher test frequencies, as further supported by values that include 32.09mΩ at 5kHz, 4.265mΩ at 20kHz, and 3.643mΩ at 100kHz.

From the comprehensive analysis of the Yageo CC1206MKX5R6BB476 series resistance performance, it is evident that it surpasses the statistical benchmark values, predominantly at higher test frequencies. Consequently, engineers seeking to incorporate a component with optimal series resistance performance into their circuits can confidently consider the Yageo CC1206MKX5R6BB476, as it presents potential advantages and exudes remarkable characteristics.

Dissipation Factor and Quality Factor

An in-depth analysis of Yageo's CC1206MKX5R6BB476 capacitor reveals insightful details about its dissipation factor (Df) and quality factor (Q) performance. Within the frequency range of 1 kHz to 250 kHz, the capacitor displays a low Df range of 0.027 to 0.766. In this same frequency span, the corresponding Q factor values vary between 36.22 and 1.30. These figures indicate that the capacitor's performance is consistent when compared to the statistical benchmark data for Ceramic: X5R capacitors, which represents the capacitor's ability to function efficiently in this frequency range.

Moreover, the CC1206MKX5R6BB476 capacitor's performance at higher voltages is noteworthy. Specifically, at 10V and within a frequency range of 1 kHz to 20 kHz, the Df maintains a low range between 0.071 and 0.014. Simultaneously, the Q factor discloses values between 14.06 and 70.90. The combined results showcase how the capacitor's performance adheres to the statistical benchmark data within this particular voltage and frequency spectrum.

Nevertheless, it is important to note that the capacitor's Df experiences a substantial upswing at frequencies above 300 kHz. At these levels, Df values oscillate between 0.389 and 2.835 for a voltage of 10V. Concurrently, the capacitor's Q factor drops below 1, indicating a downturn in efficiency at the higher frequency register. Consequently, engineers must thoroughly evaluate the intended applications and working conditions in order to assess if the CC1206MKX5R6BB476 capacitor will deliver optimal functionality and value for their specific purposes.

In summary, the Yageo CC1206MKX5R6BB476 capacitor displays satisfactory performance in terms of its dissipation factor and quality factor within certain frequency ranges and voltage conditions. These insights serve as valuable information for engineers seeking to integrate this capacitor into their designs, considering both performance efficiency and overall value for their applications.

Comparative Analysis

Conclusion

In this review, we analyzed the performance of Yageo's CC1206MKX5R6BB476 capacitor, a 47μF, Ceramic: X5R capacitor with a 10V voltage rating and a 20% tolerance, comparing it against a statistical benchmark of similar value capacitors. The analysis focused on various parameters, including impedance, capacitance, series resistance, dissipation factor, and quality factor.

In terms of impedance, the CC1206MKX5R6BB476 capacitor generally performs worse than the average benchmark values, especially at lower test frequencies. At higher test frequencies, the impedance begins to improve, coming closer to the benchmark averages. Regarding capacitance, it is observed that the CC1206MKX5R6BB476 capacitor maintains relatively stable capacitance values across most test frequencies, indicating a moderately good performance in this aspect.

The series resistance performance of the capacitor also demonstrates some variation from the benchmark. At lower test frequencies, the capacitor has slightly higher resistance values, while at higher test frequencies, it shows a more comparable performance. The dissipation factor values of the capacitor are typically higher than the benchmark, but it should be noted that in most cases, they fall within an acceptable range. Moreover, the quality factor values of the capacitor are generally lower compared to the benchmark, indicating a slightly poorer performance in terms of energy loss.

Taking all these factors into consideration, Yageo's CC1206MKX5R6BB476 capacitor presents a mixed performance compared to the benchmark data. Although its impedance and quality factor values consistently fall short of the benchmark, its capacitance and series resistance values demonstrate a more competitive performance. Engineers evaluating this capacitor for their designs should consider these findings in relation to their specific application requirements.