https://community.nxp.com/t5/Other-NXP-Products/SC16IS752-IRQ-Pull-Up-Resistor-value/m-p/2180531#M30261 <P>Dear Tim,</P> <H3>Why 1 kΩ is recommended?</H3> <OL> <LI> <P>Fast rise time for IRQ signal<BR />The IRQ pin is an open-drain output, so the pull-up resistor determines how quickly the line goes high after the device releases it.</P> <UL> <LI>With 1 kΩ at 3.3 V, the current is about 3.3 mA when the pin is low, which ensures a strong pull-up and a fast transition when released.</LI> <LI>This is important because IRQ signals often need to meet timing specs for SPI/I²C or interrupt controllers.</LI> </UL> </LI> <LI> <P>Noise immunity<BR />A strong pull-up reduces susceptibility to noise and ensures the voltage reaches a valid logic high quickly, even with some parasitic capacitance on the line.</P> </LI> </OL> <H3><STRONG>What happens with 33 kΩ?</STRONG></H3> <UL> <LI> <P><STRONG>Rise time increases significantly</STRONG> because the RC time constant grows: <SPAN class="math math-inline"><SPAN class="katex"><SPAN class="katex-mathml">τ=R×C\tau = R \times C</SPAN><SPAN class="katex-html"><SPAN class="base"><SPAN class="mord mathnormal">τ</SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord mathnormal">R</SPAN><SPAN class="mbin">×</SPAN></SPAN><SPAN class="base"><SPAN class="mord mathnormal">C</SPAN></SPAN></SPAN></SPAN></SPAN> If the line has, say, 50 pF of capacitance:</P> <UL> <LI>With 1 kΩ: <SPAN class="math math-inline"><SPAN class="katex"><SPAN class="katex-mathml">τ=1,000×50pF=50ns\tau = 1{,}000 \times 50 \text{pF} = 50 \text{ns}</SPAN><SPAN class="katex-html"><SPAN class="base"><SPAN class="mord mathnormal">τ</SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">1</SPAN><SPAN class="mord"><SPAN class="mpunct">,</SPAN></SPAN><SPAN class="mord">000</SPAN><SPAN class="mbin">×</SPAN></SPAN><SPAN class="base"><SPAN class="mord">50</SPAN><SPAN class="mord text"><SPAN class="mord">pF</SPAN></SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">50</SPAN><SPAN class="mord text"><SPAN class="mord">ns</SPAN></SPAN></SPAN></SPAN></SPAN></SPAN></LI> <LI>With 33 kΩ: <SPAN class="math math-inline"><SPAN class="katex"><SPAN class="katex-mathml">τ=33,000×50pF=1.65µs\tau = 33{,}000 \times 50 \text{pF} = 1.65 \text{µs}</SPAN><SPAN class="katex-html"><SPAN class="base"><SPAN class="mord mathnormal">τ</SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">33</SPAN><SPAN class="mord"><SPAN class="mpunct">,</SPAN></SPAN><SPAN class="mord">000</SPAN><SPAN class="mbin">×</SPAN></SPAN><SPAN class="base"><SPAN class="mord">50</SPAN><SPAN class="mord text"><SPAN class="mord">pF</SPAN></SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">1.65</SPAN><SPAN class="mord text"><SPAN class="mord">µs</SPAN></SPAN></SPAN></SPAN></SPAN></SPAN> That’s still fast for many systems, but if your interrupt latency is long and the MCU samples asynchronously, it might not matter much.</LI> </UL> </LI> <LI> <P><STRONG>Logic level stability</STRONG>: With higher resistance, leakage currents (up to 10 µA for SPI pins) could cause noticeable voltage drop. The IRQ might only reach ~3.0 V instead of 3.3 V, which is usually okay but could be marginal in noisy environments.</P> </LI> </UL> <P>&nbsp;</P> <UL> <LI>If your interrupt response time is in milliseconds and you can tolerate slower rise times, 33 kΩ is likely fine.</LI> <LI>Just ensure: <UL> <LI>Total bus capacitance isn’t huge.</LI> <LI>Leakage currents don’t pull the line below VIH (usually &gt;2 V for 3.3 V logic).</LI> </UL> </LI> </UL> <P>With Best Regards,</P> <P>Jozef</P> <P>&nbsp;</P> Mon, 06 Oct 2025 11:47:54 GMT JozefKozon 2025-10-06T11:47:54Z https://community.nxp.com/t5/Other-NXP-Products/SC16IS752-IRQ-Pull-Up-Resistor-value/m-p/2180503#M30259 <P>In the data sheet for&nbsp;SC16IS752 (and even SC16IS750) the IRQ Pull-Up Resistor value is recommended 1 kOhm for 3.3 V supply. What is the cause ? What will occur with a pullup as high as 33 kOhm ? There is no value given for the leakage current (for GPIO it's 1 µA, for SPI it's 10 µA).</P><P>We design a low power circuit with a quite long interrupt response time and would not spend 3.3 mA over several seconds when the rest of the circuit runs on 2 mA.</P> Mon, 06 Oct 2025 10:48:42 GMT https://community.nxp.com/t5/Other-NXP-Products/SC16IS752-IRQ-Pull-Up-Resistor-value/m-p/2180503#M30259 timbeyer 2025-10-06T10:48:42Z https://community.nxp.com/t5/Other-NXP-Products/SC16IS752-IRQ-Pull-Up-Resistor-value/m-p/2180531#M30261 <P>Dear Tim,</P> <H3>Why 1 kΩ is recommended?</H3> <OL> <LI> <P>Fast rise time for IRQ signal<BR />The IRQ pin is an open-drain output, so the pull-up resistor determines how quickly the line goes high after the device releases it.</P> <UL> <LI>With 1 kΩ at 3.3 V, the current is about 3.3 mA when the pin is low, which ensures a strong pull-up and a fast transition when released.</LI> <LI>This is important because IRQ signals often need to meet timing specs for SPI/I²C or interrupt controllers.</LI> </UL> </LI> <LI> <P>Noise immunity<BR />A strong pull-up reduces susceptibility to noise and ensures the voltage reaches a valid logic high quickly, even with some parasitic capacitance on the line.</P> </LI> </OL> <H3><STRONG>What happens with 33 kΩ?</STRONG></H3> <UL> <LI> <P><STRONG>Rise time increases significantly</STRONG> because the RC time constant grows: <SPAN class="math math-inline"><SPAN class="katex"><SPAN class="katex-mathml">τ=R×C\tau = R \times C</SPAN><SPAN class="katex-html"><SPAN class="base"><SPAN class="mord mathnormal">τ</SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord mathnormal">R</SPAN><SPAN class="mbin">×</SPAN></SPAN><SPAN class="base"><SPAN class="mord mathnormal">C</SPAN></SPAN></SPAN></SPAN></SPAN> If the line has, say, 50 pF of capacitance:</P> <UL> <LI>With 1 kΩ: <SPAN class="math math-inline"><SPAN class="katex"><SPAN class="katex-mathml">τ=1,000×50pF=50ns\tau = 1{,}000 \times 50 \text{pF} = 50 \text{ns}</SPAN><SPAN class="katex-html"><SPAN class="base"><SPAN class="mord mathnormal">τ</SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">1</SPAN><SPAN class="mord"><SPAN class="mpunct">,</SPAN></SPAN><SPAN class="mord">000</SPAN><SPAN class="mbin">×</SPAN></SPAN><SPAN class="base"><SPAN class="mord">50</SPAN><SPAN class="mord text"><SPAN class="mord">pF</SPAN></SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">50</SPAN><SPAN class="mord text"><SPAN class="mord">ns</SPAN></SPAN></SPAN></SPAN></SPAN></SPAN></LI> <LI>With 33 kΩ: <SPAN class="math math-inline"><SPAN class="katex"><SPAN class="katex-mathml">τ=33,000×50pF=1.65µs\tau = 33{,}000 \times 50 \text{pF} = 1.65 \text{µs}</SPAN><SPAN class="katex-html"><SPAN class="base"><SPAN class="mord mathnormal">τ</SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">33</SPAN><SPAN class="mord"><SPAN class="mpunct">,</SPAN></SPAN><SPAN class="mord">000</SPAN><SPAN class="mbin">×</SPAN></SPAN><SPAN class="base"><SPAN class="mord">50</SPAN><SPAN class="mord text"><SPAN class="mord">pF</SPAN></SPAN><SPAN class="mrel">=</SPAN></SPAN><SPAN class="base"><SPAN class="mord">1.65</SPAN><SPAN class="mord text"><SPAN class="mord">µs</SPAN></SPAN></SPAN></SPAN></SPAN></SPAN> That’s still fast for many systems, but if your interrupt latency is long and the MCU samples asynchronously, it might not matter much.</LI> </UL> </LI> <LI> <P><STRONG>Logic level stability</STRONG>: With higher resistance, leakage currents (up to 10 µA for SPI pins) could cause noticeable voltage drop. The IRQ might only reach ~3.0 V instead of 3.3 V, which is usually okay but could be marginal in noisy environments.</P> </LI> </UL> <P>&nbsp;</P> <UL> <LI>If your interrupt response time is in milliseconds and you can tolerate slower rise times, 33 kΩ is likely fine.</LI> <LI>Just ensure: <UL> <LI>Total bus capacitance isn’t huge.</LI> <LI>Leakage currents don’t pull the line below VIH (usually &gt;2 V for 3.3 V logic).</LI> </UL> </LI> </UL> <P>With Best Regards,</P> <P>Jozef</P> <P>&nbsp;</P> Mon, 06 Oct 2025 11:47:54 GMT https://community.nxp.com/t5/Other-NXP-Products/SC16IS752-IRQ-Pull-Up-Resistor-value/m-p/2180531#M30261 JozefKozon 2025-10-06T11:47:54Z