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| MITSUMI Sensor Amplifier MM1089 Sensor Amplifier Monolithic IC MM1089 Outline This IC is an amplifier with a high-impedance differential input, which can be used in high-CMR instrumentation. Particularly when amplifying signals from a high-impedance or high-bias signal source, often signals are buried in noise, making amplification difficult. This IC amplifies only the signal, and the noise is suppressed rather than amplified, making it effective for use where noise is prominent or with high-impedance signal sources. Features 1. Battery charge/discharge current detection (for laptops, word processors, etc) 2. Signal amplifiers for magnetic sensors, pressure sensors, strain gauges 3. Instrumentation amps 4. Broad input range 5. Two internal channels 80dB min., 100dB typ. Except 10M 3~ 100 -0.3V~VCC+0.3V Package SOP-18A (MM1089XF) Applications 1 Detection of battery charge/discharge current (for notebook computers, word processors etc) 2 Amplification of magnetic sensor, pressure sensor, strain gauge, other signals 3 Instrumentation amp MITSUMI Sensor Amplifier MM1089 Pin Assignment Input range switching 1 +IN1 + Rg1 -IN1 Rs1 OUT1 O.COM1 GND 1 2 3 4 A1 5 6 7 8 9 A2 14 13 12 11 10 18 17 16 15 VCC Input range switching 2 +IN2 + Rg2 -IN2 Rs2 OUT2 O.COM2 O.COM2 Pin no. Pin name Input range switching 1 Function AMP1 Input voltage range switching Hi : 1.8V~VCC+0.3V LO : -0.3V~VCC-1.8V AMP1 +Input AMP1 Resistance to set the Rg gain AMP1 Resistance to set the Rg gain AMP1 -Input AMP1 Resistance to set the Rs gain AMP1 Resistance to set the Rs gain, output 1 AMP1 Common output Ground AMP2 Common output AMP2 Resistance to set the Rs gain, output 2 AMP2 Resistance to set the Rs gain AMP2 -Input AMP2 Resistance to set the Rg gain AMP2 Resistance to set the Rg gain AMP2 +Input AMP2 Input voltage range switching Hi : 1.8V~VCC+0.3V Lo : -0.3V~VCC-1.8V Power supply input 1 INCHG1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 IN1+ Rg1+ Rg1IN1Rs1 OUT1 O.COM1 GND O.COM2 OUT2 Rs2 IN2Rg2Rg2+ IN2+ Input range switching 2 17 INCHG2 18 VCC MITSUMI Sensor Amplifier MM1089 Equivalent Circuit Diagram Absolute Maximun Ratings Item Operating temperature Storage temperature Power supply voltage Allowable loss (Ta=25C) Symbol TOPR TSTG VCC Pd Ratings -20~+70 -40~+125 -0.3~+25 350 Units C C V mW Electrical Characteristics Item Consumption current Gain Gain error Input bias current 1 Input bias current 2 Input offset current Input offset voltage O.COM pin setting voltage range O.COM pin input bias current Output offset voltage Output offset current Common-mode input range 1 Common-mode input range 2 Input voltage high level for input range switching pin Input voltage low level for input range switching pin Input current (Hi) for input range switching pin Input current (Lo) for input range switching pin Output outflow current Output inflow current Slew rate Common-mode signal rejection ratio Power supply fluctuation rejection ratio Input equivalent noise voltage (Except where noted otherwise, Ta=25C, VCC=15V, Rg=10k, Rs=1000k) Measurement conditions GV=K Rs/Rg Error of above formula When input range switching pin is high When input range switching pin is low Output takes O.COM pin voltage as reference MM1089 MM1131 VOC as reference (GV=40dB) VOC as reference (GV=40dB) When input range switching pin is high When input range switching pin is low Min. Typ. Max. Units 0.45 0.6 mA See Fig. 1 -5 0 +5 % 50 250 nA -100 -500 nA 5 50 nA -2 0 +2 mV 1.0 VCC-1.5 V nA V A V V V 0.8 VINSW=15V VINSW=0V VIN(+)-VIN(-)=+1V, VO=VCC-1.5V O.COM=5V VIN(+)-VIN(-)=-1V, VO=0.3V O.COM=5V DC DC RIN=1k, BPF=20Hz~20kHz -1 -5 1.0 0.3 80 80 4.0 1.0 0.16 100 100 6 1 -0.5 V A A mA mA V/S dB dB V -50 -100 -0.25 0 +0.25 -0.25 0 +0.25 1.8 VCC+0.3 -0.3 VCC-1.8 2.4 Symbol ICC GV GV IB1 IB2 IIO VIO VOC IOC VOO IOO VICM1 VICM2 VHSW VLSW IHSW ILSW ISOURC ISINK SR CMR SVR VNI MITSUMI Sensor Amplifier MM1089 Characteristics Common-mode input voltage range 40 30 20 SV.B 10 Voltage gain vs frequency characteristic Voltage gain GV [dB] 40 SV.A SV.B Voltage gain GV [dB] SV.A Rg=10k 30 Rg=33k 20 Rg=100k Rg=1000k 0 2 4 6 8 10 12 14 16 18 10 DC input voltage VICM [V] 101 102 103 104 105 Frequency f [Hz] Consumption voltage vs power supply voltage Consumption current ICC [mA] 0.6 Maximum output voltage vs Re 16 Maximum output voltage VOM (Vop-p) [V] 14 12 10 8 6 4 2 102 Rs=200k 103 Rs=750k Rs=500k Rs=1000k Rs=10k 0.5 0.4 6 8 10 12 14 16 18 20 22 24 Power supply voltage VCC [V] 104 105 Frequency f [Hz] Power supply fluctuation rejection ratio vs frequency Power supply fluctuation rejection ratio SVR [dB] Common mode component rejection ratio vs frequency Common mode component rejection ratio CMR [dB] 100 90 80 70 60 50 40 101 102 103 104 105 100 90 80 70 60 50 40 101 102 103 104 105 Frequency f [Hz] Frequency f [Hz] MITSUMI Sensor Amplifier MM1089 Gain Settings 1. By mounting appropriate external Rs and Rg resistances, a subtractive amp can easily be configured with a gain Gv=K RS/Rg (where K=1 typ.). Here the precision of RS and Rg affects the gain, but has no inherent effect on CMR. However, the practical range for the gain is Gv=3 to 100. 2. To determine RS and Rg, first RS is calculated from the maximum required output voltage; then the equation for the gain Gv=K RS/Rg is used to compute Rg. The voltage gain coefficient K varies with the value of Rg. For approximate values of K see Fig.1. The larger the value of RS, the larger is the output offset voltage. If RS is made small, an advantageous offset voltage is obtained, but if it is too small, an adequate maximum output voltage is not obtained. As a rough estimate, when the maximum output voltage is to be 10VP-P, Rs=1000k; if it is to be 5VP-P, then Rs=500k. Recommended values: When Rs=1000 k, Gv=100, Rg=9.1k When Rs=1000 k, Gv=50, Rg=18k When Rs=500k, Gv=50, Rg=9.1k When Rs=500k, Gv=10, Rg=47k 3. The output offset voltage ratings in the table of electrical characteristics are for Rg=10k, Rs=1000k. When using other constants, use the following formula for the output offset: Output offset=VIO GV+IOO RS 4. The output voltage is essentially the voltage applied to the O.COM (OUTPUT COMMON) pin, output as the reference level. In actuality, an offset is added to the reference potential and output. Because the O.COM pin is independent of both amps 1 and 2, offset adjustment is easily accomplished by shifting the O.COM pin voltage by the amount of the offset. 5. If the input range switching pin is set high, the input voltage range is covered from the VCC level; by switching it to low, the range extends from GND level. However, the offsets are different, so care must be taken in continuous switching. 6. The O.COM pin setting voltage range and common-mode input range should be set to voltages between the minimum and maximum values. [Voltage gain coefficient K vs. Rg] 1.00 0.98 0.96 0.94 0.92 0.90 0.88 0.86 0.84 100 101 102 103 MM1089 Voltage gain coefficient K Fig. 1 Rg (k) MITSUMI Sensor Amplifier MM1089 Application Circuits 1. Charger for NiCad batteries (charging current, discharge current detection circuit) Note : For the Rg and Rs resistances, see "Gain Settings" 2. Charger for NiCad batteries (charging current, discharge current detection circuit) Note : For the Rg and Rs resistances, see "Gain Settings" 3. Sensor signal amplification Note : For the Rg and Rs resistances, see "Gain Settings" MITSUMI Sensor Amplifier MM1089 1. Summary An instrumentation amp is often used as a sensor amp to amplify weak signals. Among the advantages of such an amplifier are 1. Good CMR characteristics 2. High input impedance 3. Means of gain adjustment which does not affect the CMR characteristic However, in practice an extremely high resistance precision is demanded, making it difficult to implement such an amplifier at low cost. In order to eliminate these problems, Mitsumi developed the MM1089 sensor amp, with a circuit configuration providing the above advantages using ordinary monolithic IC precision. 2. Aim of development The I/O environment in which this IC will be used was expected to include input sources ranging from GND to VCC, while devices receiving the IC output were anticipated to consist mainly of microcomputers with integrated D/A converters. In addition to a high CMR characteristic, the offset voltage must be kept low; here it was judged that the output voltage with no input signal could be easily read in advance and used in the microcomputer to correct measured values, so that no measures are taken to force down the offset voltage unnecessarily. Of course even if a microcomputer is not used, a potentiometer can be used to shift the reference voltage applied to the O.COM pin by the amount of the offset. Emphasis was placed on a high CMR characteristic and the ability to accommodate a wide range of input voltages. 3. Features of the MM1089 1. CMR characteristic of 100dB and higher 2. Input impedance of 10M and above 3. Broad recommended operating power supply voltage range (4.5V to 20V using a single power supply) 4. Broad input voltage range (-0.3V to VCC+0.3V) 5. Range can be set freely (between 10 and 40dB) using two external resistances 6. Reference voltage applied to O.COM pin can be set over a broad range (1V to VCC-1.5V) 4. Configuration and summary of operation 4-1. Means to achieve high CMR characteristic and circuit operation As explained above, the machining precision of ordinary monolithic ICs (with a resistance precision of 2%) is such that a high CMR characteristic cannot be easily obtained in an instrumentation amplifier. Fig. 1. Ordinary instrumentation amp In Fig.1, in a circuit configuration with a gain of 40dB, a resistance precision of 0.1% is necessary for a CMR of 100dB; for a gain of 20dB, the precision must be 0.01%. Hence in this IC a circuit configuration based on an entirely different operating principle was employed. The approach is simple: the transistor IC vs. VCE characteristic is a constant-current characteristic not readily dependent on the voltage. Hence the input signal voltage is converted into a current signal in the input unit, and the current component is passed to the output circuit. Fig.2. Basic circuit illustrating operation Figure 2 shows the basic circuit. A simple buffer amp is used to generate a difference voltage for the input signal across the resistance Rg, which determines the gain, and the current I flowing in this resistance is passed through a current mirror circuit before reaching Rs of the output amp, to obtain an output voltage I Rs. The overall gain is Rs/Rg. The output from the amp acting as an input buffer depends on two PNP transistors. The first transistor is connected to one end of the resistor Rg, a constant-current power supply, and a feedback loop; the second PNP transistor has an emitter area only one-half that of the former transistor, and is connected to a current mirror circuit and an output circuit. By this means, an output VOUT is obtained consisting of the reference voltage VCOM applied to one of the input pins of the output amp, on which MITSUMI Sensor Amplifier MM1089 is superposed the input difference voltage Rs/Rg. The common mode level of the input signal does not appear in the basic equation, meaning that an amplifier with an inherently very high CMR characteristic can be obtained. Of course in the basic circuit considered here, because of the Early effect of the transistors the current mirror circuit operation will not be ideal, and the CMR characteristic values are as yet insufficient. In the actual circuit, cascade connections suppress the Early effect, and a current mirror circuit with an extremely small voltage dependence was adopted. Further, a differential amp was not used as the input buffer amp; instead, a simple configuration was used to obtain the required characteristics. Through these circuit designs, a CMR characteristic in excess of 100dB using standard values was achieved. (4-2) Means to obtain a broad input voltage range, and circuit operation One unavoidable problem is the transistor VBE voltage, so that an input circuit which can handle all voltages from GND to VCC is inherently impossible. If a resistance is used to attenuate the input, a broad range can be achieved; but then the input impedance cannot be kept high, deviating from the original development goals. In actual environments of use there are likely to be extremely few signal sources with signals varying continuously from GND to VCC, and so a design was adopted in which it is possible to switch between a mode with an input voltage range of -0.3V to VCC-1.8 V, and a mode with input voltages ranging from 1.8V to VCC+0.3V. A switching pin was provided for this purpose. Specifically, the NPN emitter follower has an input circuit to shift the voltage in the negative direction, and the PNP emitter follower has an input circuit to shift the voltage in the positive direction; these are switched during use. Because the input offset voltage is different for the NPN and PNP inputs, in applications requiring switching during operation some special measures may be required for offset correction. (4-3) Output circuit and operation A standard op-amp circuit configuration with a Bclass output stage is adopted. The potential applied to the+input (O.COM pin) is output as the reference potential. Fig.3. Pinout To summarize the block diagram of Fig.3 and pin functions, 1. There are two circuits in a SOP-18P package. 2. Rg and Rs are external resistances. Rg is used to set the sensitivity, with smaller resistances yielding higher sensitivity. Rs is used to set the output scale; to obtain a larger output range, choose a higher resistance. Rs/Rg is the total gain. In actuality, there is a degree of error, and so a coefficient K is included (cf. Fig. 6). 3. The common voltage of the output circuit is applied to the O.COM pin; when the differential input is zero, the common voltage is output without modification (of course the offset voltage is added). When there is a differential input, the output voltage VO is VO=Vd Rs/Rg K+VC+Vof where Vd is the differential input voltage, VC is the common voltage applied to the O.COM pin, and Vof is the offset voltage. On startup the offset amount is determined automatically, and when adding correction VCOM less the offset voltage is applied. 4. Input range switching pins When the low potential is applied, the input range from -0.3V to VCC-1.8V is covered, when high, the input range is +1.8V to VCC+0.3V. Switching at TTL level is possible. However, it should be noted that the input offset voltages are different for the two ranges. Of course if the IC is to be used fixed at one range, the switching pin can be shorted to GND or to VCC. 5. Major performance parameters 1. Differential gain vs CMR characteristic Differential gain vs CMR appears in Fig. 4. When the gain of an ordinary instrumentation amp is lowered the CMR generally falls, but in this IC there is almost no change. MITSUMI Sensor Amplifier MM1089 2. Input voltage range vs gain Shown in Fig. 5. By switching the range using the input range switching pin, input from GND level to VCC level is provided. 3. Voltage gain coefficient K vs Rg Rs/Rg nearly coincides with the voltage gain, with a slight difference. This difference is represented by K, but as Rg changes K also changes. This relationship is indicated in Fig. 6. The output from the MM1089 may be passed through an A/D converter and input to a microcomputer for offset correction; an example appears in Fig.7. Here the inputs IN A and IN B are signal sources with input voltage ranges extending to GND level, while IN C and IN D are inputs which extend to VCC level. 1. An analog switch is used to input IN A to both input pins, the other switches are turned off. A control output is used to apply the "L" level to the input range switching pin. Here the output is VCOM+VOFA, and this is read by the microcomputer and stored as VA. 2. Next, an analog switch is used to input INC to both input pins; other switches are turned off. Here the input range switching pin is set to "H" by the control output. The output at this time is VCOM+VOFB, and this is read by the microcomputer and stored as VB. The above are preparatory measurements. 3. Analog switches are set so that IN A is at one input, and IN B at the other; the other switches are turned off. The control output sets the input range switching pin to "L" level. Here the measured value VX1 is the output voltage VO1 less the previously determined VA. VX1=VO1-VA=(IN A-IN B) GV 4. Analog switches are set to input IN C to one input pin and IN D to the other; the other switches are turned off. The input range switching pin is set "H" by the control output. The measured value VX2 is the output voltage VO2 less the previous VB. VX2=VO2-VB=(IN C-IN D) GV 7. Summary As explained above, an amplifier which is simple yet has a high CMR can be configured using the MM1089. The MM1089 used together with a CPU equipped with an internal D/A converter should find a broad range of applications. [dB] 130 120 MM1089 110 100 CMR 90 80 70 60 50 24 28 32 Instrumentation amp final stage Rs, Rg error 0.1% 1.0% ( ) 36 40 44 [dB] Differential gain Fig.4. CMR vs differential gain [dB] 50 Voltage gain GV 40 30 H 20 L L H L : Input range switching pin low H : Input range switching pin high 10 -2 0 2 4 6 8 10 12 14 16 18 [V] DC input voltage VICM Fig.5. Common mode input voltage range 1.00 0.98 0.96 0.94 0.92 0.90 0.88 0.86 100 Voltage gain coefficient K GV=K Rs/Rg 101 102 103 [k] Rg Fig.6. Voltage gain coefficient K vs Rg Fig.7. Application example |
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