The preferred number series produces a spacing that relates component values to their tolerances. For conventional resistors, the tolerances are ±20% (E6), ±10% (E12), ±5% (E24), ±2% (E48), and ±1% (E96). Some manufacturers produce resistors with more accurate tolerances at a higher cost. For resistors, the E96 and E192 series are less used. The gain of the inverting op-amp can be calculated using the formula: A = − R2 R1 A = − R 2 R 1, while the gain of the non-inverting op-amp is given as: A = 1 + R2 R1 A = 1 + R 2 R 1. To increase the gain, two or more op-amps are cascaded. The overall gain is then the product of the gains of each op-amp (sum if the gain is given in dB). Standard values of nominal resistance are taken from the E24 series for resistors with a tolerance of 5%, and E96 series for resistors with a tolerance of 1%. The values of the E24/E96 series are in accordance with "IEC publication 60063" Derating The power that the resistor can dissipate depends on the operating temperature; see Fig.2 E24, E48, E96 and E192 resistor values by Frida Hovsepian | Jul 13, 2016 | Caddock, Current Shunt, DC Ammeter Shunts, Digikey, Ohmite, Resistors, Ultronix, vishay, Wirewound resistors | 0 comments Resistor Tables Standard Resistor Tables (Based on EIA Preferred Values) Standard Resistor Values Tables (Based on EIA Preferred Values) This app calculates the optimum resistor values for a voltage divider circuit, incorporating all resistors in the E12, E24, E48, E96 and E192 series. yBvbbma.

e24 series resistor values