ADS1100 BAA I SBAS239 - MAY 2002 Self-Calibrating, 16-Bit ANALOG-TO-DIGITAL CONVERTER FEATURES DESCRIPTION COMPLETE DATA ACQUISITION SYSTEM IN A TINY SOT23-6 PACKAGE The ADS1100 is a precision, continuously self-calibrating Analog-to-Digital (A/D) converter with differential inputs and up to 16 bits of resolution in a small SOT23-6 package. Conversions are performed ratiometrically, using the power supply as the reference voltage. The ADS1100 uses an I2C-compatible serial interface and operates from a single power supply ranging from 2.7V to 5.5V. 16-BITS NO MISSING CODES INL: 0.0125% of FSR MAX CONTINUOUS SELF-CALIBRATION SINGLE-CYCLE CONVERSION PROGRAMMABLE GAIN AMPLIFIER GAIN = 1, 2, 4, OR 8 LOW NOISE: 4Vp-p PROGRAMMABLE DATA RATE: 8SPS to 128SPS INTERNAL SYSTEM CLOCK I2CTM INTERFACE POWER SUPPLY: 2.7V TO 5.5V LOW CURRENT CONSUMPTION: 90A APPLICATIONS The ADS1100 can perform conversions at rates of 8, 16, 32, or 128 samples per second. The onboard programmablegain amplifier, which offers gains of up to 8, allows smaller signals to be measured with high resolution. In singleconversion mode, the ADS1100 automatically powers down after a conversion, greatly reducing current consumption during idle periods. The ADS1100 is designed for applications requiring highresolution measurement, where space and power consumption are major considerations. Typical applications include portable instrumentation, industrial process control and smart transmitters. PORTABLE INSTRUMENTATION INDUSTRIAL PROCESS CONTROL A = 1, 2, 4, or 8 VIN+ SMART TRANSMITTERS CONSUMER GOODS PGA VIN- A/D Converter FACTORY AUTOMATION I2 C Interface SCL SDA VDD TEMPERATURE MEASUREMENT Clock Oscillator I2C is a registered trademark of Philips Incorporated. GND Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. Copyright (c) 2002, Texas Instruments Incorporated PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. www.ti.com ELECTROSTATIC DISCHARGE SENSITIVITY ABSOLUTE MAXIMUM RATINGS VDD to GND ........................................................................... -0.3V to +6V Input Current ............................................................... 100mA, Momentary Input Current ................................................................. 10mA, Continuous Voltage to GND, VIN+, VIN- ........................................ -0.3V to VDD + 0.3V Voltage to GND, SDA, SCL ..................................................... -0.5V to 6V Maximum Junction Temperature ................................................... +150C Operating Temperature .................................................... -40C to +85C Storage Temperature ...................................................... -60C to +150C Lead Temperature (soldering, 10s) ............................................... +300C NOTE: (1) Stresses above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. Exposure to absolute maximum conditions for extended periods may affect device reliability. This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. PACKAGE/ORDERING INFORMATION PRODUCT ADS1100 " SPECIFIED TEMPERATURE RANGE PACKAGE MARKING ORDERING NUMBER TRANSPORT MEDIA, QUANTITY ADS1100IDBVT ADS1100IDBVR Tape and Reel, 250 Tape and Reel, 3000 I2C ADDRESS(1) PACKAGE-LEAD PACKAGE DESIGNATOR(2) 1001 000 SOT23-6 DBV -40C to +85C BAAI " " " " " NOTES: (1) Contact TI or your local sales representative for more information on the availability of other addresses. (2) For the most current specifications and package information, refer to our web site at www.ti.com. PIN CONFIGURATION Top View SOT VIN- VDD SDA 6 5 4 BAAI 1 2 3 VIN+ GND SCL NOTE: Marking text direction indicates pin 1. 2 ADS1100 www.ti.com SBAS239 ELECTRICAL CHARACTERISTICS All specifications at -40C to +85C, VDD = 5V, GND = 0V, all PGAs, unless otherwise noted. ADS1100 PARAMETER ANALOG INPUT Full-Scale Input Voltage Analog Input Voltage Differential Input Impedance Common-Mode Input Impedance SYSTEM PERFORMANCE Resolution and No Missing Codes Conversion Rate Output Noise Integral Nonlinearity Offset Error Offset Drift Gain Error Gain Error Drift Common-Mode Rejection DIGITAL INPUT/OUTPUT Logic Level VIH VIL VOL Input Leakage IIH IIL POWER-SUPPLY REQUIREMENTS Power-Supply Voltage Supply Current CONDITIONS MIN (VIN+) - (VIN-) VIN+, VIN- to GND GND - 0.2 TYP MAX VDD/PGA VDD + 0.2 2.4/PGA 8 DR DR DR DR DR DR DR DR = = = = = = = = 00 01 10 11 00 01 10 11 12 14 15 16 104 26 13 6.5 See Typical Characteristic Curves DR = 11, PGA = 1, End Point Fit(1) PGA PGA PGA PGA = = = = 1 2 4 8 At DC, PGA = 8 At DC, PGA = 1 94 IOL = 3mA 0.7 * VDD GND - 0.5 GND VIH = 5.5V VIL = GND -10 VDD Power Down Active Mode 128 32 16 8 0.003 2.5/PGA 1.5 1.0 0.7 0.6 0.01 2 100 85 2.7 0.05 90 UNITS V V M M 12 14 15 16 184 46 23 11.5 Bits Bits Bits Bits SPS SPS SPS SPS 0.0125 5/PGA 8 4 2 2 0.1 % of FSR(2) mV V/C V/C V/C V/C % ppm/C dB dB 6 0.3 * VDD 0.4 V V V 10 A A 5.5 2 150 V A A 750 W W Power Dissipation VDD = 5.0V VDD = 3.0V 450 210 NOTES: (1) 99% of full-scale. (2) FSR = Full-Scale Range = 2 * VDD/PGA. ADS1100 SBAS239 www.ti.com 3 TYPICAL CHARACTERISTICS At TA = 25C, VDD = 5V, unless otherwise noted. SUPPLY CURRENT vs TEMPERATURE 120 SUPPLY CURRENT vs I2C BUS FREQUENCY 250 225 VDD = 5V 200 IVDD (A) IVDD (A) 100 80 25C 175 125C 150 125 100 60 VDD = 2.7V -40C 75 50 40 -60 -40 -20 0 20 40 60 80 100 120 10 140 100 OFFSET ERROR vs TEMPERATURE 2.0 10k OFFSET ERROR vs TEMPERATURE 2.0 VDD = 5V VDD = 2.7V 1.0 1.0 PGA = 8 PGA = 4 PGA = 2 Offset Error (mV) Offset Error (mV) 1k I2C Bus Frequency (kHz) Temperature (C) PGA = 1 0.0 -1.0 PGA = 8 PGA = 4 PGA = 2 PGA = 1 0 40 80 0.0 -1.0 -2.0 -60 -40 -20 0 20 40 60 80 100 120 -2.0 140 -60 -40 -20 Temperature (C) 20 60 100 120 140 Temperature (C) GAIN ERROR vs TEMPERATURE GAIN ERROR vs TEMPERATURE 0.010 0.04 VDD = 5V VDD = 2.7V 0.03 PGA = 8 PGA = 4 PGA = 1 Gain Error (%) Gain Error (%) 0.02 0.005 0.01 0.00 -0.01 -0.02 PGA = 2 PGA = 4 PGA = 8 0.000 -0.005 PGA = 1 -0.010 PGA = 2 -0.015 -0.03 -0.020 -0.04 -60 -40 -20 0 20 40 60 80 100 120 140 4 -60 -40 -20 0 20 40 60 80 100 120 140 Temperature (C) Temperature (C) ADS1100 www.ti.com SBAS239 TYPICAL CHARACTERISTICS At TA = 25C, VDD = 5V, unless otherwise noted. INTEGRAL NONLINEARITY vs SUPPLY VOLTAGE TOTAL ERROR vs INPUT SIGNAL 0.0 0.016 -0.5 Total Error (mV) PGA = 4 -1.0 PGA = 2 -1.5 -2.0 Data Rate = 8SPS PGA = 1 -2.5 -100 PGA = 8 PGA = 4 PGA = 2 PGA = 1 0.014 Integral Nonlinearity (% of FSR) PGA = 8 0.012 0.010 0.008 0.006 0.004 0.002 0.000 -75 -50 -25 0 25 50 75 100 2.5 3.0 3.5 4.0 Input Signal (% of Full-Scale) INTEGRAL NONLINEARITY vs TEMPERATURE 5.0 5.5 NOISE vs INPUT SIGNAL 0.05 20 PGA =1 Data Rate = 8SPS PGA = 8 0.04 0.03 Noise (p-p, % of LSB) Integral Nonlinearity (% of FSR) 4.5 VDD (V) VDD = 2.7V 0.02 VDD = 3.5V VDD = 5V 15 PGA = 4 PGA = 2 10 PGA = 1 5 0.01 0 0.00 -60 -40 -20 0 20 40 60 80 100 120 0 140 20 60 80 100 NOISE vs TEMPERATURE NOISE vs SUPPLY VOLTAGE 25 30 Data Rate = 8SPS PGA = 8 PGA = 8 20 PGA = 4 15 PGA = 2 10 Noise (p-p, % of LSB) 25 Noise (p-p, % of LSB) 40 Input Signal (% of Full-Scale) Temperature (C) 20 15 10 5 PGA = 1 Data Rate = 8SPS 5 0 2.5 3.0 3.5 4.0 4.5 5.0 -60 5.5 ADS1100 SBAS239 -40 -20 0 20 40 60 80 100 120 140 Temperature (C) VDD (V) www.ti.com 5 TYPICAL CHARACTERISTICS At TA = 25C, VDD = 5V, unless otherwise noted. DATA RATE vs TEMPERATURE 10 FREQUENCY RESPONSE 0 Data Rate = 8SPS VDD = 2.7V -20 Gain (dB) Data Rate (SPS) 9 8 VDD = 5V 7 -40 -60 -80 Data Rate = 8SPS -100 6 -60 -40 -20 0 20 40 60 80 100 120 0.1 140 Temperature (C) 6 1 10 Input Frequency (Hz) 100 1k ADS1100 www.ti.com SBAS239 THEORY OF OPERATION The ADS1100 is a fully differential, 16-bit, self-calibrating, delta-sigma A/D converter. Extremely easy to design with and configure, the ADS1100 allows you to take high-quality measurements with a minimum of effort. The ADS1100 consists of a delta-sigma A/D converter core with adjustable gain, a clock generator, and an I2C interface. Each of these blocks are described in detail in the sections that follow. ANALOG-TO-DIGITAL CONVERTER The ADS1100's A/D converter core consists of a differential switched-capacitor delta-sigma modulator followed by a digital filter. The modulator measures the difference between the positive and negative analog inputs and compares this to a reference voltage, which, in the ADS1100, is the power supply. The digital filter receives a high-speed bitstream from the modulator and outputs a code, which is a number proportional to the input voltage. OUTPUT CODE CALCULATION The output code is a scalar value which is (except for clipping) proportional to the voltage difference between the two analog inputs. The output code is confined to a finite range of numbers; this range depends on the number of bits needed to represent the code. The number of bits needed to represent the output code for the ADS1100 depends on the data rate, as shown in Table I. Data rate Number of Bits Minimum Code Maximum Code 8SPS 16SPS 32SPS 128SPS 16 15 14 12 -32768 -16384 -8192 -2048 32767 16383 8191 2047 puts codes in binary two's complement format, so the absolute values of the minima and maxima are not the same; the maximum n-bit code is 2n-1 - 1, while the minimum n-bit code is -1 * 2n-1. For example, the ideal expression for output codes with a data rate of 16SPS and PGA = 2 is: Output Code = 16384 * 2 * (V ) - (V ) IN+ IN - VDD The ADS1100 outputs all codes right-justified and signextended. This arrangement makes it possible to perform averaging on the higher data rate codes using only a 16-bit accumulator. Output codes for various input levels are shown in Table II. SELF-CALIBRATION The previous expressions for the ADS1100's output code do not account for the gain and offset errors in the modulator. To compensate for these, the ADS1100 incorporates self-calibration circuitry. The self-calibration system operates continuously, and requires no user intervention. No adjustments can be made to the self-calibration system, and none need to be made. The self-calibration system cannot be deactivated. The offset and gain error figures shown in the specifications table include the effects of calibration. CLOCK GENERATOR The ADS1100 features an onboard clock generator, which drives the operation of the modulator and digital filter. The Typical Characteristics show varieties in data rate over supply voltage and temperature. It is not possible to operate the ADS1100 with an external modulator clock. TABLE I. Minimum and Maximum Codes. INPUT IMPEDANCE For a minimum output code of Min Code, gain setting of PGA, positive and negative input voltages of VIN+ and VIN-, and power supply of VDD, the output code is given by the expression: Output Code = -1* Min Code * PGA * (V ) - (V ) IN+ IN - VDD In the above expression, it is important to note that the negated minimum output code is used. The ADS1100 out- The ADS1100 uses a switched-capacitor input stage. To external circuitry, it looks roughly like a resistance. The resistance value, as with all switched-capacitor circuits, depends on the capacitor values and the rate at which they are switched. The switching frequency is the same as the modulator frequency; the capacitor values depend on the PGA setting. The switching clock is generated by the onboard clock generator, so its frequency, nominally 275 kHz, is somewhat dependent on supply voltage and temperature. Input Signal Data Rate Negative Full-Scale -1 LSB Zero +1 LSB Positive Full-Scale 8 SPS 16 SPS 32 SPS 128 SPS 8000H C000H E000H F800H FFFFH FFFFH FFFFH FFFFH 0000H 0000H 0000H 0000H 0001H 0001H 0001H 0001H 7FFFH 3FFFH 1FFFH 07FFH TABLE II. Output Codes for Different Input Signals. ADS1100 SBAS239 www.ti.com 7 The common-mode and differential input impedances are different. For a gain setting of PGA, the differential input impedance is typically: 2.4M / PGA The common mode impedance is typically 8M. The typical value of the input impedance often cannot be neglected. Unless the input source has a low impedance, the ADS1100's input impedance may affect the measurement accuracy. For sources with high output impedance, buffering may be necessary. Bear in mind, however, that active buffers introduce noise, and also introduce offset and gain errors. All of these factors should be considered in high-accuracy applications. Because the clock generator frequency drifts slightly with temperature, the input impedances will also drift. For many applications, this input impedance drift can be neglected, and the typical impedance values above can be used. ALIASING If frequencies are input to the ADS1100 which exceed half the data rate, aliasing will occur. To prevent aliasing, the input signal must be bandlimited. Some signals are inherently bandlimited, for example, a thermocouple's output, which has a limited rate of change, but may nevertheless contain noise and interference components. These can fold back into the sampling band just as any other signal can. The ADS1100's digital filter provides some attenuation of high frequency noise, but the filter's sinc1 frequency response cannot completely replace an anti-aliasing filter; some external filtering may still be needed. For many applications, a simple RC filter will suffice. When designing an input filter circuit, remember to take the interaction between the filter network and the input impedance of the ADS1100 into account. USING THE ADS1100 OPERATING MODES The ADS1100 operates in one of two modes: continuous conversion and single conversion. In continuous conversion mode, the ADS1100 continuously performs conversions. Once a conversion has been completed, the ADS1100 places the result in the output register, and immediately begins another conversion. When the ADS1100 is in continuous conversion mode, the ST/BSY bit in the configuration register always reads 1. In single conversion mode, the ADS1100 waits until the ST/BSY bit in the conversion register is set to 1. When this happens, the ADS1100 powers up and performs a single conversion. After the conversion completes, the ADS1100 places the result in the output register, resets the ST/BSY bit to 0 and powers down. Writing a 1 to ST/BSY while a conversion is in progress has no effect. When switching from continuous conversion mode to single conversion mode, the ADS1100 will complete the current conversion, reset the ST/BSY bit to 0 and power down. 8 RESET AND POWER-UP When the ADS1100 powers up, it automatically performs a reset. As part of the reset, the ADS1100 sets all of the bits in the configuration register to their default setting. The ADS1100 responds to the I2C General Call Reset command. When the ADS1100 receives a General Call Reset, it performs an internal reset, exactly as though it had just been powered on. I2C INTERFACE The ADS1100 communicates through an I2C (Inter-Integrated Circuit) interface. The I2C interface is a 2-wire opendrain interface supporting multiple devices and masters on a single bus. Devices on the I2C bus only drive the bus lines LOW, by connecting them to ground; they never drive the bus lines HIGH. Instead, the bus wires are pulled HIGH by pull-up resistors, so the bus wires are HIGH when no device is driving them LOW. This way, two devices cannot conflict; if two devices drive the bus simultaneously, there is no driver contention. Communication on the I2C bus always takes place between two devices, one acting as the master and the other acting as the slave. Both masters and slaves can read and write, but slaves can only do so under the direction of the master. Some I2C devices can act as masters or slaves, but the ADS1100 can only act as a slave device. An I2C bus consists of two lines, SDA and SCL. SDA carries data; SCL provides the clock. All data is transmitted across the I2C bus in groups of eight bits. To send a bit on the I2C bus, the SDA line is driven to the bit's level while SCL is LOW. (A LOW on SDA indicates a zero bit; a HIGH indicates a one bit.) Once the SDA line has settled, the SCL line is brought HIGH, then LOW. This pulse on SCL clocks the SDA bit into the receiver's shift register. The I2C bus is bidirectional: the SDA line is used both for transmitting and receiving data. When a master reads from a slave, the slave drives the data line; when a master sends to a slave, the master drives the data line. The master always drives the clock line. The ADS1100 never drives SCL, because it cannot act as a master. On the ADS1100, SCL is an input only. Most of the time the bus is idle, no communication is taking place, and both lines are HIGH. When communication is taking place, the bus is active. Only master devices can start a communication. They do this by causing a start condition on the bus. Normally, the data line is only allowed to change state while the clock line is LOW. If the data line changes state while the clock line is HIGH, it is either a start condition or its counterpart, a stop condition. A start condition is when the clock line is HIGH and the data line goes from HIGH to LOW. A stop condition is when the clock line is HIGH and the data line goes from LOW to HIGH. After the master issues a start condition, it sends a byte which indicates which slave device it wants to communicate with. This byte is called the address byte. Each device on an I2C bus has a unique 7-bit address to which it responds. (Slaves can also have 10-bit addresses; see the I2C specifi- ADS1100 www.ti.com SBAS239 cation for details.) The master sends an address in the address byte, together with a bit which indicates whether it wishes to read from or write to the slave device. Every byte transmitted on the I2C bus, whether it be address or data, is acknowledged with an acknowledge bit. When a master has finished sending a byte, eight data bits, to a slave, it stops driving SDA and waits for the slave to acknowledge the byte. The slave acknowledges the byte by pulling SDA LOW. The master then sends a clock pulse to clock the acknowledge bit. Similarly, when a master has finished reading a byte, it pulls SDA LOW to acknowledge this to the slave. It then sends a clock pulse to clock the bit. (Remember that the master always drives the clock line.) A not-acknowledge is performed by simply leaving SDA HIGH during an acknowledge cycle. If a device is not present on the bus, and the master attempts to address it, it will receive a not-acknowledge because no device is present at that address to pull the line LOW. When a master has finished communicating with a slave, it may issue a stop condition. When a stop condition is issued, the bus becomes idle again. A master may also issue another start condition. When a start condition is issued while the bus is active, it is called a repeated start condition. A timing diagram for an ADS1100 I2C transaction is shown in Figure 1. Table III gives the parameters for this diagram. t(LOW) ADS1100 I2C ADDRESS The ADS1100's I2C address is 1001aaa, where aaa are bits set at the factory. The ADS1100 is shipped with aaa set to zero, so its address is 1001000. Contact Texas Instruments for information about the availability of other addresses. I2C GENERAL CALL The ADS1100 responds to General Call Reset, which is an address byte of 00H followed by a data byte of 06H. The ADS1100 acknowledges both bytes. On receiving a General Call Reset, the ADS1100 performs a full internal reset, just as though it had been powered off and then on. If a conversion is in process, it is interrupted; the output register is set to zero; and the configuration register is set to its default setting. The ADS1100 always acknowledges the General Call address byte of 00H, but it does not acknowledge any General Call data bytes other than 04H or 06H. I2C DATA RATES The I2C bus operates in one of three speed modes: Standard, which allows a clock frequency of up to 100kHz; Fast, which allows a clock frequency of up to 400kHz; and High- tF tR t(HDSTA) SCL t(HDSTA) t(HIGH) t(HDDAT) t(SUSTO) t(SUSTA) t(SUDAT) SDA t(BUF) P S S P FIGURE 1. I2C Timing Diagram. FAST MODE PARAMETER SCLK Operating Frequency Bus Free Time Between STOP and START Condition MIN f(SCLK) HIGH-SPEED MODE MAX MIN 0.4 MAX UNITS 3.4 MHz t(BUF) 600 160 ns t(HDSTA) 600 160 ns Repeated START Condition Setup Time t(SUSTA) 600 160 ns STOP Condition Setup Time t(SUSTO) 600 160 ns Data Hold Time t(HDDAT) 0 0 ns Data Setup Time t(SUDAT) 100 10 ns SCLK Clock LOW Period t(LOW) 1300 160 ns SCLK Clock HIGH Period t(HIGH) 600 60 ns Hold Time After Repeated START Condition. After this period, the first clock is generated. Clock/Data Fall Time tF 300 160 ns Clock/Data Rise Time tR 300 160 ns TABLE III. Timing Diagram Definitions. ADS1100 SBAS239 www.ti.com 9 speed mode (also called Hs mode), which allows a clock frequency of up to 3.4MHz. The ADS1100 is fully compatible with all three modes. In continuous conversion mode, the ADS1100 ignores the value written to ST/BSY. When read in single conversion mode, ST/BSY indicates whether the A/D converter is busy taking a conversion. If ST/ BSY is read as 1, the A/D converter is busy, and a conversion is taking place; if 0, no conversion is taking place, and the result of the last conversion is available in the output register. No special action needs to be taken to use the ADS1100 in Standard or Fast modes, but High-speed mode must be activated. To activate High-speed mode, send a special address byte of 00001XXX following the start condition, where the XXX bits are unique to the Hs-capable master. This byte is called the Hs master code. (Note that this is different from normal address bytes: the low bit does not indicate read/write status.) The ADS1100 will not acknowledge this byte; the I2C specification prohibits acknowledgment of the Hs master code. On receiving a master code, the ADS1100 will switch on its High-speed mode filters, and will communicate at up to 3.4MHz. The ADS1100 switches out of Hs mode with the next stop condition. In continuous mode, ST/BSY is always read as 1. Bits 6-5: Reserved Bits 6 and 5 must be set to zero. Bit 4: SC For more information on High-speed mode, consult the I2C specification. SC controls whether the ADS1100 is in continuous conversion or single conversion mode. When SC is 1, the ADS1100 is in single conversion mode; when SC is 0, the ADS1100 is in continuous conversion mode. The default setting is 0. REGISTERS Bits 3-2: DR The ADS1100 has two registers which are accessible via its I2C port. The output register contains the result of the last conversion; the configuration register allows you to change the ADS1100's operating mode and query the status of the device. Bits 3 and 2 control the ADS1100's data rate, as shown in Table VI. DR1 DR0 OUTPUT REGISTER The 16-bit output register contains the result of the last conversion in binary two's complement format. Following reset or power-up, the output register is cleared to zero; it remains zero until the first conversion is completed. Therefore, if you read the ADS1100 just after reset or power-up, you will read zero from the output register. Bits 1-0: PGA Bits 1 and 0 control the ADS1100's gain setting, as shown in Table VII. PGA1 CONFIGURATION REGISTER 6 5 4 3 NAME ST/BSY 0 0 SC 2 DR1 DR0 PGA0 GAIN 0(1) 1 0 1 1(1) 2 4 8 0(1) 0 1 1 NOTE: (1) Default Setting. You can use the 8-bit configuration register to control the ADS1100's operating mode, data rate, and PGA settings. The configuration register's format is shown in Table IV. The default setting is 8CH. 7 128SPS 32SPS 16SPS 8SPS(1) TABLE VI. DR Bits. The output register's format is shown in Table V. BIT DATA RATE 0 0 0 1 1 0 1(1) 1(1) NOTE: (1) Default Setting TABLE VII. PGA Bits. 1 0 PGA1 PGA0 READING FROM THE ADS1100 TABLE IV. Configuration Register. You can read the output register and the contents of the configuration register from the ADS1100. To do this, address the ADS1100 for reading, and read three bytes from the device. The first two bytes are the output register's contents; the third byte is the configuration register's contents. Bit 7: ST/BSY The meaning of the ST/BSY bit depends on whether it is being written to or read from. You do not always have to read three bytes from the ADS1100. If you want only the contents of the output register, read only two bytes. In single conversion mode, writing a 1 to the ST/BSY bit causes a conversion to start, and writing a 0 has no effect. BIT 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 NAME D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 TABLE V. Output Register. 10 ADS1100 www.ti.com SBAS239 Reading more than three bytes from the ADS1100 has no effect. All of the bytes beginning with the fourth will be FFH. do this, address the ADS1100 for writing, and write one byte to it. This byte is written into the configuration register. A timing diagram for an ADS1100 read operation is shown in Figure 2. Writing more than one byte to the ADS1100 has no effect. The ADS1100 will ignore any bytes sent to it after the first one, and it will only acknowledge the first byte. WRITING TO THE ADS1100 A timing diagram for an ADS1100 write operation is shown in Figure 3. You can write new contents into the configuration register (you cannot change the contents of the output register). To 1 9 1 9 ... SCL SDA 1 0 0 1 A2 A1 A0 D15 R/W Start By Master D14 ACK By ADS1100 SDA (Continued) ... 9 D7 D6 D5 D4 D3 D2 D10 D9 ... D8 ACK By Master Frame 2: Output Register Upper Byte 1 ... D12 D11 From ADS1100 Frame 1: I2C Slave Address Byte SCL (Continued) D13 D1 1 ST/ BSY D0 From ADS1100 9 0 0 SC ACK By Master DR1 DR0 PGA1 PGA0 ACK By Master From ADS1100 Frame 3: Output Register Lower Byte Stop By Master Frame 4: Configuration Register (Optional) FIGURE 2. Timing Diagram for Reading From the ADS1100. 1 9 1 9 SCL SDA 1 0 0 1 A2 A1 A0 R/W Start By Master ST/ BSY 0 0 SC DR1 DR0 PGA1 PGA0 ACK By ADS1100 Frame 1: I2C Slave Address Byte ACK By ADS1100 Stop By Master Frame 2: Configuration Register FIGURE 3. Timing Diagram for Writing to the ADS1100. ADS1100 SBAS239 www.ti.com 11 PACKAGE DRAWING MPDS026D - FEBRUARY 1997 - REVISED FEBRUARY 2002 DBV (R-PDSO-G6) PLASTIC SMALL-OUTLINE 0,95 6X 6 0,50 0,25 0,20 M 4 1,70 1,50 1 0,15 NOM 3,00 2,60 3 Gage Plane 3,00 2,80 0,25 0 -8 0,55 0,35 Seating Plane 1,45 0,95 0,05 MIN 0,10 4073253-5/G 01/02 NOTES: A. B. C. D. 12 All linear dimensions are in millimeters. This drawing is subject to change without notice. Body dimensions do not include mold flash or protrusion. Leads 1, 2, 3 may be wider than leads 4, 5, 6 for package orientation. 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