Introduction

The Yageo CC0603KRX7R7BB105 is a Ceramic X7R surface mount capacitor with a nominal value of 1μF, a tolerance of ±10%, and a voltage rating of 16V in a 0603 (1608 Metric) package. In this review, we will be analyzing the performance of this capacitor in comparison to a statistical benchmark formed from data obtained from other components with the same nominal value. The goal is to present an unbiased, insightful, and accurate evaluation of the Yageo CC0603KRX7R7BB105's suitability for inclusion in electronic circuits.

For your convenience, here is a summarized list of pros and cons for the Yageo CC0603KRX7R7BB105:

• Wide range of test frequency measurements
• Consistent performance across multiple test frequencies
• High quality factor at certain test frequencies
• Reliable impedance and dissipation factor measurements

• Higher series resistance values at lower test frequencies
• Lower series capacitance values at higher test frequencies
• Missing data at certain test frequencies, especially within the 650 kHz to 1 MHz range

The following sections of this review will detail the results of our analysis, focusing on capacitance, series resistance, dissipation factor, and quality factor measurements. We will be comparing the Yageo CC0603KRX7R7BB105's performance to a statistical benchmark based on a dataset of measurements from similar components to determine whether it is a suitable choice for your electronic circuit needs.

Impedance

When comparing the component's impedance at a 1 Volt test condition against the statistical benchmark values, we observe that the results typically fall within the minimum and maximum range of the benchmark values. At lower test frequencies of 5 Hz to 100 Hz, the impedance values are slightly below the average benchmark impedance. Notably, at 50 Hz, the component's impedance is 3.048k Ohms compared to the benchmark's average impedance of 3.385k Ohms. Similarly, at 100 Hz, the capacitor's impedance measures 1.529k Ohms, slightly less than the benchmark's average value of 1.702k Ohms. Thus, in the low-frequency range, the component displays marginally better-than-average impedance performance.

As we progress to higher frequencies, the capacitor's impedance tends to move closer to the benchmark's average values, indicating a generally stable performance. For instance, at 1 kHz, 10 kHz, and 20 kHz, the capacitor yields impedance values of 156.2, 17.01, and 8.693 Ohms, respectively, closely matching the benchmark's average impedance values of 174.7, 20.47, and 10.88 Ohms. It is important to note that, at specific test frequencies such as 5 kHz and 50 kHz, the component's impedance matches the benchmark's minimum value, which suggests that the capacitor might have wider performance variability at specific frequencies.

Evaluating the component's impedance at 10 Volts test conditions reveals a similar trend. At lower test frequencies, the capacitor performs comparatively better with marginally lower impedance values than the benchmark's average values. As the test frequency increases, the component's impedance moves closer to the benchmark average values, reflecting a consistent performance across various voltage levels and test frequencies.

The Yageo CC0603KRX7R7BB105 demonstrates satisfactory impedance performance when compared against the statistical benchmark values, with a tendency to perform marginally better at lower test frequencies and converging towards the benchmark averages at higher frequencies. The component's mainly stable performance serves as a valuable asset for engineers considering this capacitor for their projects. However, minor fluctuations in impedance values should be taken into consideration at specific test frequencies. To optimize the capacitor's performance in particular applications, engineers should carefully study and analyze these fluctuations.

Capacitance

Upon analyzing the Yageo CC0603KRX7R7BB105's capacitance values across various test frequencies and voltages, it is evident that the component performs differently depending on the circumstances. A detailed assessment of this ceramic X7R capacitor's performance under different conditions provides valuable insights for electronics engineers.

When testing the capacitor at 1V, the capacitance values outperform both the average and maximum benchmark values for frequencies below 1 kHz. This accomplishment demonstrates exceptional low-frequency capacitance performance and consistent reliability across a range of applications where low-frequency stability is crucial.

However, as the test frequencies increase beyond 1 kHz, the Yageo CC0603KRX7R7BB105 series capacitance falls below the benchmark average value. Despite still falling within the minimum and maximum benchmark range, this slight decline indicates room for improvement in the capacitor's high-frequency performance. Enhancing high-frequency characteristics would serve to widen its applicability and optimize its use in electronic circuits.

Interestingly, when evaluating the capacitance measurements at 10V, the results reveal higher series capacitance values across all test frequencies, compared to 1V. The performance remains constant up to approximately 1 kHz, and after 5 kHz, the capacitor surpasses the statistical benchmarks. Thus, the Yageo CC0603KRX7R7BB105 showcases excellent high-voltage stability—an essential quality for a ceramic X7R capacitor. The capacitor's ability to maintain consistent capacitance in high-voltage environments broadens its usage spectrum and allows engineers to depend on its performance across diverse operating conditions.

Series Resistance

An in-depth analysis of the Yageo CC0603KRX7R7BB105 capacitor was conducted to evaluate its performance in terms of series resistance at 1 Volt. The test data reveals a wide spectrum of series resistance values that are influenced significantly by the varying test frequencies. It is essential to compare these values with the statistical benchmarks to determine the component's efficiency.

Beginning with a lower frequency of 5 Hz, the series resistance measures at 794.5 Ohms, perfectly matching the benchmark value. At the 10 Hz frequency, the value decreases to 392.6 Ohms, which is close to the minimum series resistance in the benchmark for this frequency. Progressing to higher frequencies such as 50 Hz and 100 Hz enhances the component's efficiency with series resistance values measured at 79.01 Ohms and 40.83 Ohms, respectively, positioning them near the lower boundaries of the benchmark.

Further testing at 500 Hz and 1 kHz yields series resistance measurements of 8.534 Ohms and 4.184 Ohms, which, although slightly higher than the benchmark's minimum, can still be considered to be below average. It is important to note that the data for the component is not available for test frequencies beyond this point, resulting in an incomplete comparison with the benchmark.

Focusing on the component's LCR measurements at 10 Volts reveals that the CC0603KRX7R7BB105 consistently maintains series resistance values below the benchmark's average up until 20 kHz. It is worth mentioning that the capacitor achieves very low series resistance values of 1.298 Ohms at 5 kHz and 567.6m Ohms at 10 kHz, significantly outperforming the benchmark averages.

Overall, the analysis shows that the Yageo CC0603KRX7R7BB105 capacitor exhibits favorable performance in terms of series resistance when matched against the statistical benchmark, especially in the lower frequency ranges. However, the lack of data at higher test frequencies restricts a comprehensive evaluation. Therefore, additional testing and data collection at higher frequencies are strongly advised to gain a thorough understanding of the component's capabilities.

Dissipation Factor and Quality Factor

In this review, we assessed the dissipation factor (Df) and the quality factor (Q) of the Yageo CC0603KRX7R7BB105 capacitor in comparison to the statistical benchmark data gathered from capacitors with similar specifications. These factors are crucial for understanding the capacitor's performance in terms of energy loss and energy storage efficiency, respectively.

Starting with the LCR measurements at 1 Volt, the dissipation factor (Df) remained fairly consistent across test frequencies ranging from 5 Hz to 20 kHz, with a value of around 0.026, which can be considered low compared to the benchmark. This indicates that the Yageo capacitor experiences relatively low energy loss during operation within this voltage range. In the same voltage range, quality factor (Q) values spanned from 37.98 at 5 Hz to the significantly higher value of 283.60 at 20 kHz, demonstrating a varying degree of energy storage efficiency throughout the tested frequencies.

Moving on to the LCR measurements at 10 Volts, the dissipation factor (Df) revealed an increase as opposed to the measurements at 1 Volt, with values ranging from 0.034 at 5 Hz to 0.047 at 1 kHz. Although higher than the 1 Volt range, these values remained comparative to the statistical benchmark. This suggests that the energy loss in the capacitor is more pronounced at higher operating voltages. Within this voltage range, the quality factor (Q) underwent a noticeable decrease, with values spanning from 21.74 at 10 Hz to 44.11 at 20 kHz, illustrating that the capacitor's energy storage efficiency was adversely affected at higher voltages. Overall, this evaluation permits users to understand the Yageo capacitor's performance in different operating conditions, allowing them to make informed decisions when incorporating it into their electronic systems.

Comparative Analysis

Conclusion

In conclusion, when comparing the Yageo CC0603KRX7R7BB105 capacitor's performance against the statistical benchmark data, it's evident that this component aligns with most of the benchmark values. At low frequencies, the capacitor's impedance and series resistance are close to the benchmark figures. As the test frequency increases, the observed trends in impedance, series resistance, and quality factor are satisfactory, although some deviation is observed at higher frequencies.

However, despite these deviations, the general performance of Yageo's CC0603KRX7R7BB105 still falls within acceptable ranges for ceramic X7R capacitors. It's also worth noting that the series capacitance values demonstrate a stable and consistent performance across the entire range of test frequencies. Overall, this capacitor appears to be a reliable option and can be considered suitable for various circuits requiring such components.

Ultimately, engineers assessing this specific capacitor for their applications should find the provided data insightful and useful when making choices on the suitability of this Yageo ceramic capacitor in their electronic circuits. As a Ceramic X7R capacitor, it delivers relatively stable capacitance characteristics while offering a compact package that works well for Surface Mount needs.