AM467

Precision amplifier for bridge circuits AM467 PRINCIPLE FUNCTION Adjustable amplification of differential input voltage signals (from 0 to ±5 mV FS up to 0 to ±100 mV FS) to an adjustable, ratiometric output voltage of 0.2V to Vcc-0.2 V _ VCC = 5V+5% Differential input voltages __ (+ 5...+100mV FS) A M467 VOUT =0,2...VCC -0,2V (adjustable) e.g.0,5...4,5V ratiometric TYPICAL APPLICATIONS • • • • Amplifiers for ceramic sensing elements Amplifiers for DMS sensing elements Amplifiers for GMR sensing elements For industrial and automotive applications analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 1/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 TABLE OF CONTENTS PRINCIPLE FUNCTION TYPICAL APPLICATIONS FEATURES GENERAL DESCRIPTION BLOCK DIAGRAM ELECTRICAL SPECIFICATIONS DESCRIPTION OF FUNCTIONS EXAMPLE APPLICATION The procedure in detail (for calibration with discrete resistors) DIMENSIONING NOTES BLOCK DIAGRAM and PINOUT FURTHER READING 1 1 3 3 3 4 5 5 6 7 8 8 9 analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 2/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 FEATURES • Wide differential input voltage range (±5 mV FS...±100 mV FS) • Low offset • Low offset drift • Low input noise • High CMRR: > 120 dB • Wide operating temperature range: – 40 °C... +125 °C • Adjustable output voltage • Rail-to-rail output stage: VOUT = 0.2 V ... VCC – 0.2 V • Sink/source output • Single ratiometric supply: VCC = 5 V • Integrated EMV protective functions • Overvoltage protection 12 V • Integrated ESD protective functions • Short-circuit-proofing • Small-scale design GENERAL DESCRIPTION AM457 is a high-precision integrated amplifier which has been developed to condition signals from small differential input voltages within a range of a few millivolts (±5 to ±100 mV FS). The chief component of the IC is a highly accurate, low-noise amplifier circuit which can be adjusted to the sensing elements using an external network of resistors. With the exception of the additional operational amplifier and the diagnostic unit IC AM467's pins and functions are compatible with the AM457. The rail-to-rail output makes the IC suitable for the amplification of DMS and piezoceramic sensing elements and GMR measuring cells with respect to the specific calibration network. BLOCK DIAGRAM VCC 8 AM467 IN- 2 IN+ 3 Inputamplifier Output stage 1 OUT Biasing Unit Short circuit protection Current limitation 4 GND Figure 1: Block diagram for AM467 analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 3/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 ELECTRICAL SPECIFICATIONS (with reference to the example application) Tamb = 25°C, VCC = 5V (unless otherwise stated) Parameter Voltage Range Quiescent Current Temperature Specifications Operating Storage Junction Amplifier AMP Offset Voltage VOS vs. Temperature VOS vs. Temperature Input Bias Current IB vs. Temperature Differential Input Voltage Input Offset Current IOS vs. Temperature Input Resistance Input Capacitance Common Mode Input Range Common Mode Rejection Ratio Open Loop Gain Adjustable Gain Output Voltage Range Guaranteed Max Output Current Output Load Resistance Power Supply Rejection Ratio Gain Bandwidth Product Non Linearity Slew Rate Input Voltage Noise Overvoltage Protection SR en VOS dVOS/dT dVOS/dT IB dIB/dT VIN IOS dIOS/dT RIN CIN CMIR CMRR G0 G VOUT IOUT RL PSRR GBW R1,2=1k Rk=10k, C1=1nF, Ck=100pF, no RL NL = G/Go, G ≤ 100 C1 = 1nF; RL = 20kΩ Rs = 100Ω; VCC = 5V ; fg=1kHz with Rs = Source Impedance 0.2 0.3 13.5 20 12 Sink and source C1 = 1nF; Iout = 1µA Tamb= -45 … 105°C Tamb= 105 … 125°C VCM = 2.5V Tamb= -45…125°C VIN =Vout+ – VoutSee Figure 2 VCM = 2.5V Tamb= -45 … 125°C VCM / IB,typ (VCM = 2.5V) By design 1 100 120 10 0.2 250 20 90 190 110 310 10-4 V/µs nV/√Hz V VCC – 0.2 V µA kΩ dB kHz 120 140 ±0.5 ±2.5 80 90 3.7 ±5 ±30 nA pA/°C MΩ pF V dB dB ±5 30 –0.13 ±0.1 ±0.5 ±0.3 ±3 ±6 200 –0.6 ±100 mV µV/°C µV/°C nA nA/°C mV Tamb Tst TJ –45 –55 125 150 150 °C °C °C Symbol VCC ICC Tamb = – 40 ... +125°C Conditions Min. 4.5 170 Typ. 5 320 Max. 5.5 530 Unit V µA = VOUT / I OUT , sink and source Table 1: Specifications Currents flowing into the IC are negative. VCM = Input Common Mode Voltage analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 4/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 EXTERNAL COMPONENTS Parameter Output Capacitor Compensation Capacitor Stabilization Capacitor (optional) EMV Protection Capacitor (optional) Load Resistor to GND, to VCC Symbol C1 C2 C3 C4 RL Vout = max. Vout 20 Conditions Min. 1 100 100 470 Typ. Max. 5 Unit nF pF nF pF kΩ Table 2: External components of the calibration network Recommended: ceramic capacitors DESCRIPTION OF FUNCTIONS AM457 is an integrated precision circuit for the signal amplification of high-impedance signal sources and for the signal conditioning of sensor bridges with low sensitivity, particularly for ceramic and DMS sensing elements or GMR measuring cells. The IC generates a rail-to-rail output signal of 0.2 V to Vcc-0.2 V. The amplification and offset can be set independently of one another using external resistors. Through the suitable dimensioning of external resistors in particular an output voltage of 0.5...4.5 V can also be provided. As these values are standard the following description refers to this output voltage. AM467 works on the principle of ratiometry with a supply voltage of 5 V ±5%. The IC is distinguished by its low offset and extremely low thermal offset drift across a wide temperature range, enabling it to be classified as a precision amplifier. The sink and source output stage is protected internally against short-circuiting. The AM467 design incorporates protective measures against interference from EMV and ESD using suitable semiconductor structures. With the exception of the additional operational amplifier and the diagnostic unit the IC is compatible with AM457. AM467 thus has a smaller chip surface and a lower power consumption. AM467 can be used as an autonomous signal conditioning IC or as a preamplifier for an A/D converter for back-end digitization. EXAMPLE APPLICATION AM457 is suitable for the amplification of resistance networks connected up as a Wheatstone bridge with four resistors and which have a low sensitivity, such as 1.0 to 3.5 mV/V with a 5 V supply, for example. By way of example a sensor application is described herein which is analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 5/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 based on a piezoceramic sensing element such as the above and is to be calibrated to an output signal of 0.5...4.5 V (sensor system). The basic calibration procedure The sensor system is calibrated in two stages. Using a mathematical algorithm (Excel sheet: Cali_AM467_rev1.xls) and taking AM467's measured output voltage values and the individual sensor bridge values as a basis, the values for the two resistors (calibration resistors) are calculated. In the calibration of the system all effective errors (parasitic effects and component tolerances) are taken into account. The sensing element is first measured and secondly the electrical characteristics of the sensor using predefined precision measuring resistors. This information is then processed in an Excel program to calculate the setpoint for two of the calibration resistors which are then swapped with the given measuring resistors and added to the circuit accordingly. If necessary, in a second stage the offset of the output voltage can be corrected using the information given in the Excel sheet. The procedure in detail (for calibration with discrete resistors) In order to evaluate the sensor system signal four resistors (R1 to R4) are required (see Figure 2). The values of the two resistors R2 and R4 are fixed for the network and do not have to be adjusted during calibration. Like capacitors C1 to C4 they can be mounted on the circuit board at the outset. Resistors R1 and R3 act as measuring resistors and are assembled on the measuring apparatus for all sensor systems in one sensing element category (see Dimensioning). Their values must be as close as possible to those calculated by Analog Microelectronics for the relevant sensing element category. With the described components (R1 to R4 and C1 to C4) the sensor signal is at its operating point which then enables calibration. For this purpose a few of the electrical characteristics of the sensing element are first determined without the evaluation circuitry being connected (Stage 1). Using the Excel calibration software (Kali_AM467.xls) the necessary calibration parameters are: the sensing element resistance (RBR), average output voltage of the sensing element (VBR) and the system's supply voltage (VCC). Once these three values have been determined the sensing element is connected up to the evaluation circuit. The output signal at the AM467 IC (Out1 and Out2) is measured at zero and full pressure (offset and full scale signal) and entered into the Excel program with the bridge values including the values for the given maximum pressure of the sensing element (Pmax). Taking these values and applying them to a calibration algorithm the two resistors R1 and R3 are calculated separately for each individual system. These then replace the measuring resistors and have to be soldered onto the circuit board. analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 6/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 Resistors R1 and R3 are described as calibration resistors. These stipulate the final operating point. Once these resistors have been mounted the calibration procedure is complete. Depending on the accuracy of the resistors used an offset value of 0.5 V and a full scale signal of 4.5 V should have been obtained. Should the expected final accuracy require it, in an additional second stage (Stage 2) the offset of the output voltage can be corrected using resistor R1. To this end the AM467 output must again be measured at P = 0 bar. If at 0 bar the output is too high or too low by a few millivolts, for example, the Excel program then calculates the necessary second correction of R1 in ohms. The offset error which is then obtained if a different resistance is used in place of calculated resistance R1 can also be determined by the Excel sheet. The sensitivity in mV/ohm is instrumental here, providing information as to by how many millivolts the offset shifts when the used resistor R1 has a delta R (in ohms) to the calculated value. The given sensitivity value (mV/ohm) is multiplied by the delta R of resistor R1 to obtain a change in offset which affects both the offset (0.5 V) and the full scale signal (4.5 V). AM467 R3 8 VCC C1 IN+ C4 IN3 R1 AMP 2 Output stage with short circuit proofing 4 GND 1 OUT R2 R4 Vout C3 C2 GND Figure 3: Ceramic sensing element with AM467 and a calibration network with external resistors. DIMENSIONING In the combination of ceramic sensing element and AM467 the operating point (the initial value of the four resistors R1 to R4) was determined for all sensing elements in a specific sensing element category. In the case of piezoceramic sensors the term "sensing element category" is used to denote sensing elements with the following characteristics: analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 7/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 Bridge resistance: 11 kOhm ± 20% Sensitivity: 2.4 ± 1 mV/V Offset: 0 to ± 0.3 mV/V Supply voltage: 5 V ± 10% The following values are obtained for the above sensing element categories: Fixed resistor R2 = 33 k; accuracy of 1% Fixed resistor R4 = 12 k; accuracy of 1% Measuring resistor R1 = 11 k; accuracy of 0.1% Measuring resistor R3 = 120 k; accuracy of 0.1% C1 = 100 nF (optional) C2 = 100 pF (ceramic) C3 = 1 nF to 5 nF (ceramic) C4 = 470 pF optional (ceramic) NOTES For bridge circuits with characteristics other than the above (with other sensing element categories, such as DMS sensing elements, for example) Analog Microelectronics can adapt the dimensioning program on request. An Excel program (Cali_AM467_rev1.xls) is used for calibration (the calculation of the definitive operating point). This is available on the www.analogmicro.de website. DIAGRAM and PINOUT AM467 8 VCC IN+ 3 IN2 + - AMP Output stage with short circuit proofing 1 OUT OUT ININ+ GND 1 2 3 4 8 7 6 5 VCC N.C. N.C. N.C. 4 GND Figure 4: AM467 Pinout Figure 3: Diagram of AM467 analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 8/9 Rev. 1.0 Precision amplifier for bridge circuits AM467 PIN 1 2 3 4 5 6 7 8 NAME OUT ININ+ GND EXPLANATION Output Negative Input Positive Input IC Ground No function No function No function 5V Supply Voltage N.C. N.C. N.C. VCC Table 3: Pin configuration for AM467 For package dimensions see: http://www.analogmicro.de/products/analogmicro.de.en.package.pdf FURTHER READING As AM467 is identical in its specifications to AM457 – with the exception of the diagnosis – the calibration guidelines given for the latter also apply to AM467, available at www.analogmicro.de for various different networks. AN1009 Application description AN1011 Calibration for DMS sensing elements AN1012 Calibration for piezoceramic sensing elements DELIVERY OPTIONS AM467 is available as: • An SOP 8 • Dice in a 4" wafer on 5" blue foil (on request) NOTES Analog Microelectronics reserves the right to make amendments to dimensions, technical data and any other information without prior notice. analog microelectronics Analog Microelectronics GmbH An der Fahrt 13, D – 55124 Mainz Internet: http://www.analogmicro.de Phone: Fax: Email: +49 (0)6131/91 073 – 0 +49 (0)6131/91 073 – 30 info@analogmicro.de February 2007 9/9 Rev. 1.0