Introduction

In this technical review, the performance of the CSRN2512FKR100, a Thick Film Resistor manufactured by Stackpole Electronics Inc., will be analyzed and compared to a statistical benchmark formed from other components of the same value. The purpose of this review is to provide an unbiased, detailed, and scrutinizing examination of the Resistor's performance, with the target audience being degreed engineers considering the use of this Resistor in their products.

The CSRN2512FKR100 Resistor boasts a nominal value of 100mΩ with ±1% tolerance, making it suitable for various applications. It features Surface Mount mounting and comes in the 2512 (6332 Metric) package. Below are some pros and cons for this component:

• Consistent performance across a wide range of test frequencies
• Lower impedance and resistance values at high frequencies compared to benchmark
• Low dissipation factor at low test frequencies

• Higher impedance and resistance values at low frequencies compared to benchmark
• Unclear Quality Factor or Dissipation Factor at certain frequencies

In the following sections of the review, we will evaluate the Resistance, Inductance, and perform a Comparative Analysis of the CSRN2512FKR100 Resistor with respect to the benchmark data provided. This expert evaluation aims to deliver inspiring, insightful, enlightening, and valid information to assist in making the right decision for your product needs.

Impedance

An in-depth analysis of the impedance performance of the CSRN2512FKR100 Thick Film Resistor proves essential for engineers and product designers to comprehensively understand its effects on their projects. By comparing its specifications with provided statistical benchmark data, we can explore its reliability and performance compared to other similar components available.

Observing the CSRN2512FKR100 Resistor's LCR measurements at 1V, we find that it exhibits impedance values that are slightly higher than the average impedance observed in the benchmark. For instance, at a test frequency of 5Hz, the impedance is 102.6mΩ, compared to the average benchmark impedance of 91.73mΩ. This trend persists across all test frequencies in this voltage range, with the most significant impedance disparity being approximately 12.7mΩ at 1MHz. These elevated impedance values at lower frequencies may impact certain applications negatively, depending on the circuit's sensitivity to impedance variations.

However, upon examining the LCR measurements at 10V, while the early test frequencies (5Hz to 1kHz) showcase higher impedance than the average benchmark, an interesting phenomenon occurs at higher test frequencies. At 50kHz, the impedance (93.19mΩ) falls below the average of the benchmark (92.22mΩ). It continues to remain below the average until the 600kHz test frequency. This behavior suggests that the CSRN2512FKR100 Resistor may exhibit superior performance for applications primarily designed to operate at these higher test frequencies.

Conducting a thorough impedance analysis of the CSRN2512FKR100 Thick Film Resistor allows engineers to make informed decisions regarding its suitability for their specific applications. It also highlights the importance of understanding the unique impedance performance of this component to ensure optimal performance in various circuit designs and specialized applications.

Resistance

In this review section, we systematically analyze and compare the resistance performance of Stackpole Electronics Inc's CSRN2512FKR100 Resistor to the statistical benchmark of components with the same value, across a range of frequencies and voltages. Our assessment aims to provide enlightening insights into this particular component's behavior and characteristics.

Upon thorough evaluation of the data provided for various frequencies and voltages, a few key observations emerge. The CSRN2512FKR100, a Thick Film Resistor with a nominal value of 100m Ohms and a tight tolerance of ±1%, exhibits a consistently higher series resistance compared to the benchmark's average values at 1 Volt LCR measurements. This resistor's series resistance ranges from 102.3m to 102.6m Ohms across all tested frequency bands, while the average benchmark values are found to be slightly lower, spanning from 91.71m to 93.43m Ohms.

Similarly, when subjected to 10 Volts LCR measurements, the CSRN2512FKR100 maintains a comparable pattern in terms of deviation from the statistical benchmark series resistance data at lower frequency bands (ranging between 118.6m and 123.8m Ohms). However, a notable shift is observed when going beyond the 50kHz frequency range, where the series resistance measurements move closer to the benchmark data. For instance, it measures 93.08m Ohms at 50k, (compared to the benchmark's 92.15m Ohms) and 102.5m Ohms at the 1MHz frequency range (benchmark: 93.43m Ohms).

From the above analysis, it is apparent that the CSRN2512FKR100 Resistor demonstrates consistent resistance performance while varying in its deviation from the statistical benchmark's average values at different frequency bands, particularly at lower frequencies. Engineers should take these insightful findings into account when evaluating the suitability of this Thick Film Resistor for a particular circuit application, ensuring optimal performance and reliable operation.

Inductance

Diving deeper into the LCR measurements of the CSRN2512FKR100 under various test conditions, let us first examine the inductance measurements conducted at 1 Volt. In the frequency range of 1 kHz, the series inductance is registered at 6.17 nH, which is notably lower than the average series inductance from the benchmark data. This could signify less energy is stored within the inductor for this specific frequency, resulting in overall better or worse performance, depending on the application needs.

Moving to the 10 kHz frequency range, the CSRN2512FKR100 exhibits an inductance of 4.52 nH, which compares quite favorably against the benchmark average of 7.925 nH. In this scenario, a smaller deviation from the benchmark data might indicate better linearity and less parasitic impedance across the component.

Switching our attention to the LCR measurements conducted at 10 Volts, we find different results. In the higher 100 kHz frequency range, the CSRN2512FKR100 achieves an inductance of 1.862 nH - a value that competes well against the benchmark average of 6.597 nH. A noteworthy point is that the inductance at higher frequencies tends to decrease due to the skin effect and other phenomena. A lower inductance in high-frequency applications could lead to better performance when employed in many high-speed circuit designs.

Furthermore, it is important to mention an instance in our analysis where the CSRN2512FKR100 did not provide a measured value at the 20 kHz frequency range. Unfortunately, the lack of information limits our ability to undertake a comprehensive comparison with the benchmark dataset within this specific frequency range. While this does not necessarily imply performance issues, it is crucial to understand the potential impact of such data unavailability in different real-world applications and circuit implementation.

Comparative Analysis

While reviewing the performance of Stackpole Electronics Inc's CSRN2512FKR100, a Thick Film Resistor with a nominal value of _marshaled

Conclusion

In conclusion, the CSRN2512FKR100 resistor from Stackpole Electronics Inc performs differently in comparison to the statistical benchmark data of other components with the same value. Generally, at 1 Volt test frequency, the impedance tends to be higher than the average value from the statistical benchmark data; this indicates that this resistor could offer more resistance at lower frequencies. Further, as the test frequency increases, the series inductance slightly differs in some instances from the statistical benchmark data.

When tested at 10 Volts, it is observed that the impedance measurements are inconsistent with the values in the statistical benchmark data. It is important to note that at 50 kHz test frequency, the observed impedance significantly deviates from the benchmark. Therefore, electronic engineers who are keen to use the CSRN2512FKR100 resistor should proceed with caution while focusing on these discrepancies in regards to the application they wish to use it in.

Overall, the CSRN2512FKR100 resistor provides a unique performance profile compared to the statistical benchmark data. Depending on the intended application and desired frequency range, it can be evaluated as a suitable resistor or call for a need for alternatives to ensure optimal circuit performance. Engineers are encouraged to factor in these considerations before deciding whether the CSRN2512FKR100 is the right choice for their engineering projects.