Introduction

The Samsung Electro-Mechanics CL03A105KP3NSNC is a ceramic X5R capacitor with a nominal value of 1μF and a tolerance of ±10% at 10V voltage rating. This surface mount component utilizes a 0201 (0603 Metric) package. This review will analyze the performance of the CL03A105KP3NSNC Capacitor against the statistical benchmarks formed from the components of the same value, with a focus on the capacitance, series resistance, dissipation factor, and quality factor in multiple test frequencies and voltage conditions.

• Pros:
  • High degree of benchmark deviations at various test frequencies
  • Low dissipation factor at lower frequencies


• Cons:
  • Series capacitance below nominal value in some test conditions
  • Reduced performance at higher frequencies

Impedance

In this performance analysis of the Samsung Electro-Mechanics CL03A105KP3NSNC capacitor, we will delve into impedance measurements and compare them against a comprehensive statistical benchmark. By analyzing the data at different test frequencies, we can identify discrepancies between the Samsung CL03A105KP3NSNC impedance compared to the average impedance value across the benchmark. Understanding these discrepancies offers insights into the component's performance characteristics and assists engineers in making informed decisions.

For instance, at a test frequency of 100 kHz, the CL03A105KP3NSNC capacitor has an impedance of 2.642 Ohm, which is higher than the benchmark average impedance of 2.408 Ohm. Similarly, at 1 MHz, the component features an impedance of 289.8m Ohm, surpassing the benchmark average impedance of 262.2m Ohm. Such disparities in impedance values can lead to differences in the overall performance of a circuit.

Notably, this trend prevails across various other test frequencies. At 10 kHz, the CL03A105KP3NSNC measures an impedance of 21.62 Ohm, compared to the benchmark average impedance of 20.47 Ohm. At 50 kHz, the component impedance is 5.027 Ohm, exceeding the benchmark average impedance of 4.638 Ohm. These deviations are important indicators when assessing the performance characteristics of capacitors.

However, there are cases where the CL03A105KP3NSNC impedance values are outperformed by the benchmark data. For instance, at a test frequency of 5 kHz, the component has an impedance of 40.63 Ohm, while the benchmark average impedance stands at 38.38 Ohm. Similarly, at a 20 kHz test frequency, the values are 11.6 Ohm and 10.88 Ohm, respectively. In these specific cases, the Samsung capacitor exhibits less favorable impedance characteristics compared to the benchmark data.

Overall, the Samsung Electro-Mechanics CL03A105KP3NSNC capacitor's impedance performance deviates from the desired statistical benchmark values across a range of test frequencies. As impedance is a crucial aspect when assessing capacitors for use in circuits, engineers should thoroughly scrutinize these impedance variations when considering the CL03A105KP3NSNC for their applications. A thoughtful evaluation process can help engineers determine whether this capacitor meets the specific requirements of their applications and ensure optimal overall performance.

Capacitance

In this section, we examine the performance of the Samsung Electro-Mechanics CL03A105KP3NSNC capacitor, focusing on its capacitance across various frequencies and voltages. The capacitor's nominal value is 1μF with a tolerance of ±10%, striving to maintain stable capacitance over an extensive range of frequencies and voltages.

Upon assessing the LCR measurements of the CL03A105KP3NSNC at 1 volt relative to the benchmark data, it becomes apparent that this capacitor performs within the average range for lower frequency tests, specifically from 5 Hz to 1 kHz. For instance, at 5 Hz, the capacitance measures 844.3nF, which is relatively close to the average benchmark capacitance of 962.5nF. Similarly, at 10 Hz and 50 Hz, its capacitance registers at 840.6nF and 833.3nF, respectively, which also aligns closely with the benchmark average.

Nonetheless, inconsistencies arise as we move towards higher frequencies. The observed capacitance begins to deviate from the benchmark and shows less consistency in performance. At 5 kHz, the CL03A105KP3NSNC's capacitance drops to 782.8nF, below the average benchmark value of 833nF. As the frequency increases even further, this gap enlarges. Unfortunately, there is insufficient data available beyond 200 kHz for a comprehensive comparison to the benchmark.

Upon evaluating LCR measurements at 10 volts, a similar trend materializes. In the lower frequency range (5 Hz to 1 kHz), the component performs comparably close to or below the average benchmark. From 5 kHz onwards, there is a more pronounced deviation. The capacitor's capacitance increases up to 843.2nF at 50 kHz, but then decreases at higher frequencies, which is contrary to the benchmark's higher capacitance values spanning from 654nF to 898.8nF.

In conclusion, the Samsung Electro-Mechanics CL03A105KP3NSNC capacitor demonstrates favorable performance in lower frequencies, closely meeting the average statistical benchmark. However, inconsistent capacitance values in higher frequencies suggest that engineers should carefully assess the suitability of this component when integrating it into their circuits, particularly in applications requiring higher-frequency performance.

Series Resistance

An in-depth analysis of the series resistance of the CL03A105KP3NSNC capacitor is essential to understand its performance characteristics and determine its suitability for various engineering applications. The capacitor's performance is evaluated against statistical data provided at two different test voltage levels: 1 Volt and 10 Volts, with various frequencies ranging from 5 Hz to 1 kHz. By comparing these test results with the benchmark data, a comprehensive understanding of the component's capabilities can be obtained.

At the 1 Volt test level, the CL03A105KP3NSNC capacitor demonstrates a somewhat lower series resistance of 1.585k Ohms at 5 Hz compared to the benchmark's average value of 1.641k Ohms. When the test frequency is increased to 10 Hz, the series resistance slightly improves at 798.9 Ohms, which is comparable to the benchmark's average of 827.4 Ohms. Remarkably, as the test frequency reaches 50 Hz, the series resistance decreases to 164.3 Ohms, offering better performance compared to the benchmark's average of 171.3 Ohms. This trend of lower series resistance is consistently observed at higher frequencies such as 100 Hz and 500 Hz when compared with their benchmark averages.

With regards to the 10 Volts test, the capacitor initially exhibits a higher series resistance value of 2.418k Ohms at 5 Hz when compared to the benchmark data. However, as the test frequency increases to 10 Hz and beyond, the capacitor demonstrates lower values. For example, the series resistance is 382 Ohms at 10 Hz and 226.2 Ohms at 50 Hz. Maintaining this trend, the component's series resistance remains consistently lower at higher frequencies like 100 Hz, 500 Hz, and 1 kHz when compared with the benchmark's average values.

Through the evaluation of the series resistance at various test frequencies, the CL03A105KP3NSNC capacitor demonstrates promising performance, making it a viable choice for many engineering applications. The lower series resistance values observed across most of the tested frequencies indicate the capacitor's ability to manage power dissipation effectively, which contributes significantly to the improvement of circuit efficiency in a multitude of scenarios.

Dissipation Factor and Quality Factor

Upon analyzing the statistical benchmark data for the Samsung Electro-Mechanics CL03A105KP3NSNC at 1V in contrast to capacitors with a comparable value, we observed a relatively low dissipation factor (Df) range of 0.042 to 0.056 in test frequencies spanning from 5 to 10kHz. This outcome signifies favorable energy dissipation characteristics, making it a strong contender for utilization in power electronics and RF applications. Remarkably, at 50kHz, a notable quality (Q) value of 76.97 was recorded, positioning this capacitor as a reliable choice for high-performance applications across various domains.

As we progress to the 10V LCR measurements, the CL03A105KP3NSNC demonstrates even better results. The dissipation factor exhibits a significant decrease, reaching as low as 0.008 at 10Hz. This indicates exceptional energy efficiency in this voltage range. Furthermore, within the 10 to 50kHz test frequency scope, the Quality Factor remains consistently high, even peaking at 235.65 at 10Hz. These results emphasize the robust overall performance of the CL03A105KP3NSNC at 10V, suggesting its suitability for high-speed circuits that incorporate a combination of analog and digital applications.

Comparative Analysis

Conclusion

In conclusion, after a thorough analysis of the Samsung Electro-Mechanics CL03A105KP3NSNC X5R ceramic capacitor, it can be deduced that its performance is generally on par with the statistical benchmark for capacitors of the same value. The capacitor's impedance values are consistently within the acceptable range, and its quality factor demonstrates acceptable performance when compared with the benchmark data.

However, it should be noted that the CL03A105KP3NSNC's capacitance values show a significant decline with increasing test frequency, particularly at high voltage (10 Volts) levels, which may be a concern for engineers seeking an optimal capacitor choice. Moreover, its series resistance values remain fairly consistent throughout various test frequencies, indicating that further improvements could be made in this regard.

In summary, the Samsung Electro-Mechanics CL03A105KP3NSNC capacitor offers satisfactory performance when compared to the statistical benchmark but falls short in some areas, particularly with capacitance values at higher test frequencies and voltage levels. Engineers should carefully assess their specific requirements to determine if this capacitor is the optimal choice for their applications.