ADC128D818 ADC128D818 12-Bit, 8-Channel, ADC System Monitor with Temperature Sensor, Internal/External Reference, and I 2 C Interface Literature Number: SNAS483D ADC128D818 12-Bit, 8-Channel, ADC System Monitor with Temperature Sensor, Internal/External Reference, and I2C Interface 1.0 General Description 3.0 Features The ADC128D818 I2CTM system monitor is designed for max- imum flexibility. The system monitor can be configured for single-ended and/or pseudo-differential inputs. An on-board temperature sensor, combined with WATCHDOG window comparators, and an interrupt output pin, INT, allow easy monitoring and out-of-range alarms for every channel. A high performance internal reference is also available to provide for a complete solution in the most difficult operating conditions. The ADC128D818's 12-bit delta-sigma ADC supports Standard Mode (Sm, 100 kbits/s) and Fast Mode (Fm, 400kbits/s) I2C interfaces. The ADC128D818 includes a sequencer to control channel conversions and stores all converted results in independent registers for easy microprocessor retrieval. Unused channels can be shut down independently to conserve power. The ADC can use either an internal 2.56V reference or a variable external reference. An analog filter is included on the I2C digital control lines to provide improved noise immunity. The device also includes a TIMEOUT reset function on SDA and SCL to prevent I2C bus lock-up. The ADC128D818 operates from +3.0 to +5.5V power supply voltage range, -40C to 125C temperature range, and the device is available in a 16-pin TSSOP package. 2.0 Applications Communications Infrastructure Thermal / Hardware Server Monitors System Monitors Industrial and Medical Systems Electronic Test Equipment and Instrumentation Power Supply Monitoring / Supervision 12-bit Resolution Delta-Sigma ADC Local Temperature Sensing Configurable Single-Ended and/or Pseudo-Diff. Inputs +2.56V Internal VREF or Variable External VREF WATCHDOG Window Comparators with Status and Mask Registers of All Measured Values Independent Registers for Storing Measured Values INT Output Notifies Microprocessor of Error Event I2C Serial Bus Interface Compatibility 9 Selectable Addresses TIMEOUT Reset Function to Prevent I2C Bus Lock-Up Individual Channel Shutdown to Limit Power Consumption Deep Shutdown Mode to Minimize Power Consumption TSSOP 16-Lead Package 4.0 Key Specifications ADC Resolution 12-bit Supply Voltage Range +3.0V to +5.5V Total Unadjusted Error -0.45/+0.2% Integral Non-Linearity 1LSb Differential Non-Linearity 1LSb Operating Current 0.56 mA Deep Shutdown Current 10 A Temperature Resolution 0.5C/LSb Temp. Accuracy (-40C to 125C) 3C Temp. Accuracy (-25C to 100C) 2C 5.0 Typical Application 30096301 I2C(R) is a registered trademark of the Philips Corporation. (c) 2011 National Semiconductor Corporation 300963 www.national.com ADC128D818 12-Bit, 8-Channel, ADC System Monitor with Temperature Sensor, Internal/ External Reference, and I2C Interface January 10, 2011 ADC128D818 6.0 Ordering Information Temperature Range -40C TA +125C Order Number Device Marking ADC128D818CIMT ADC128D818CIMTX ADC128D81 8CIMT 6.0 Connection Diagram NS Package Number Specified Power Supply Voltage MO-153 +3.0V to +5.5V 30096302 7.0 Pin Descriptions Pin Number Pin Name(s) ESD Structure Type Description 1 VREF Analog Input ADC external reference. ADC128D818 allows two choices for sourcing VREF: internal or external. If the +2.56V internal VREF is used, leave this pin unconnected. If the external VREF is used, source this pin with a voltage between +1.25V and V+. At Power-On-Reset (POR), the default setting is the internal VREF. Bypass with the parallel combination of 1 F (electrolytic or tantalum) and 0.1 F (ceramic) capacitors. 2 SDA Digital I/O Serial Bus Bidirectional Data. NMOS open-drain output. Requires external pull-up resistor to function properly. 3 SCL Digital Input 4 GND GROUND 5 V+ POWER 6 INT Digital Output Interrupt Request. Active Low, NMOS, open-drain. Requires external pull-up resistor to function properly. 7-8 A0 - A1 Tri-Level Inputs Tri-Level Serial Address pins that allow 9 devices on a single I2C bus. 9 - 16 IN7 - IN0 Analog Inputs www.national.com 2 Serial Bus Clock. Requires external pull-up resistor to function properly. Internally connected to all of the circuitry. +3.0V to +5.5V power. Bypass with the parallel combination of 1 F (electrolytic or tantalum) and 0.1 F (ceramic) bypass capacitors. The full scale range will be controlled by the internal or external VREF. These inputs can be assigned as singleended and/or pseudo-differential inputs. ADC128D818 8.0 Block Diagram 30096303 9.0 Product Highlights The maximum number of channels that can be enabled for each input mode are shown in the table below. Unusued channels may be disabled through software. TABLE 1. Input Modes Modes of Operation Single-Ended Inputs Pseudo-Differential Inputs 0 7 - 1 88 1 8 - - 96 2 - 4 1 52 3 4 2 1 76 3 Internal Temperature Cycle Time with Maximum Measurement Number of Channels Enabled (ms - typ). www.national.com ADC128D818 TABLE 2. Conversion Modes Conversion Modes Description Continuous Enabled channels are measured continuously. Low Power Enabled channels are measured, then the device is automatically placed into shutdown mode. This cycle is repeated every 728 ms. One-Shot When One-Shot Register (address 09h) is programmed while the device is in shutdown or deep shutdown mode, the device will initiate a single conversion and comparison cycle, after which the device returns to the respective mode it was in. www.national.com 4 1, Note 2) If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office/ Distributors for availability and specifications. Supply Voltage (V+): Voltage on SCL, SDA, A0, A1, INT: Voltage on IN0-IN7, VREF: Input Current at Any Pin (Note 3): Package Input Current (Note 3): Maximum Junction Temperature (TJMAX): (Note 4) ESD Susceptibility (Note 6) Human Body Model: Machine Model: 11.0 Operating Ratings 6.0V -0.3V to 6.0V -0.3V to (V+ + 0.3)V and 6.0V 5 mA 30 mA Supply Voltage (V+): Voltage on SCL, SDA, A0, A1, INT: Voltage on IN0-IN7, VREF: 3.0V to 5.5V -0.05V to 5.5V -0.05V to (V+ + 0.05)V and 5.5V TMIN = -40C TMAX = 125C Temperature Range for Electrical Characteristics: 150C (Note 1, Note 2) -40C TA +125C Operating Temperature Range: Junction to Ambient Thermal Resistance (JA): (Note 5) 3,000V 300V 130C/W 12.0 DC Electrical Characteristics The following specifications apply for +3.0 VDC V+ +5.5 VDC , External VREF = +2.56V, unless otherwise specified. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = 25C (Note 7). Min (Note 9) Typical (Note 8) Max (Note 9) Units Supply Voltage 3.0 3.3 or 5.0 5.5 V External Reference Voltage 1.25 2.56 V+ V Symbol Parameter Conditions POWER SUPPLY CHARACTERISTICS V+ VREF I+ 2.56 Internal Reference Voltage Supply Current (see the "Power Management" section for more information). V 23 ppm/C Interface Inactive, V+ = 5.5V, Mode 2 0.74 mA Interface Inactive, V+ = 3.6V, Mode 2 0.56 mA Shutdown Mode, V+ = 5.5V 0.65 mA Shutdown Mode, V+ = 3.6V 0.48 mA 10 A 3 C 2 C Deep Shutdown Mode (Note 10). TEMPERATURE-to-DIGITAL CONVERTER CHARACTERISTICS Temperature Error -40C TA +125C -25C TA +100C Resolution 0.5 C 0.625 mV ANALOG-to-DIGITAL CONVERTER CHARACTERISTICS n Resolution 12-bit with full-scale at VREF = 2.56V. External VREF = 1.25V, PseudoDifferential, V+ = 3.0V to 3.3V. (Note 10) INL Integral Non-Linearity External VREF = 2.56V, PseudoDifferential External VREF = 5.0V, PseudoDifferential, V+ = 5.0V to 5.5V. DNL Differential Non-Linearity (Note 13) 5 -1 0.36 1 LSb -2 1.58 4 LSb -1 0.25 1 LSb www.national.com ADC128D818 Charged Device Model: 1,000V Storage Temperature -65C to +150C For soldering specifications, see product folder at www.national.com and www.national.com/ms/MS/MS-SOLDERING.pdf 10.0 Absolute Maximum Ratings (Note ADC128D818 Symbol Parameter Conditions Internal VREF, Single-Ended, V+ = 3.0V to 3.6V. Internal VREF, Single-Ended, V+ = 4.5V to 5.5V (Note 12). Internal VREF, Pseudo-Differential, V+ = 3.0V to 3.6V or V+ = 4.5V to 5.5V (Note 12). TUE Total Unadjusted Error (Note 11) External VREF = 1.25V, Single-Ended, V+ = 3.0V to 3.6V. External VREF = 2.56V, Single-Ended, V+ = 3.0V to 5.5V. External VREF = 1.25V, PseudoDifferential, V+ = 3.0V to 3.6V. External VREF = 2.56V, PseudoDifferential, V+ = 3.0V to 5.5V. Min (Note 9) Typical (Note 8) Max (Note 9) Units -0.5 0.5 % of FS -0.3 0.5 % of FS -0.6 0.1 % of FS -0.45 0.2 % of FS -0.25 0.45 % of FS -0.45 0.2 % of FS -0.15 0.2 % of FS -0.5 0.1 % of FS -0.2 0.15 % of FS Internal VREF, V+ = 3.0V to 3.6V. Internal VREF, V+ = 4.5V to 5.5V (Note 12) GE Gain Error External VREF = 1.25V or 2.56V, V+ = 3.0V to 3.6V. External VREF = 2.56V or 5.0V, V+ = 4.5V to 5.5V. Internal VREF, PseudoDifferential, V+ = 4.5V to 5.5V (Note 12). External VREF = 1.25V or 2.56V, Single-Ended, V+ = 3.0V to 3.6V. OE Offset Error External VREF = 2.56V or 5.0V, SingleEnded, V+ = 4.5V to 5.5V External VREF = 1.25V or 2.56V, Pseudo-Differential, V+ = 3.0V to 3.6V. External VREF = 2.56V or 5.0V, Pseudo-Differential, V+ = 4.5V to 5.5V Continuous Conversion Mode tC Low Power Conversion Mode Each Enabled Voltage Channel 12 ms Internal Temperature Sensor 3.6 ms Enabled Voltage Channel(s) and Internal Temperature Sensor 728 ms MULTIPLEXER / ADC INPUT CHARACTERISTICS RON On Resistance ION Input Current (On Channel Leakage Current) 0.005 A IOFF Off Channel Leakage Current 0.005 A 2 10 k DIGITAL OUTPUTS: INT VOUT(0) Logical "0" Output Voltage IOUT = +5.0 mA at V+ = +4.5V, IOUT = +3.0 mA at V+ = +3.0V 0.4 V OPEN DRAIN SERIAL BUS OUTPUT: SDA VOUT(0) Logical "0" Output Voltage IOUT = +3.0 mA at V+ = +4.5V, IOH High Level Output Current VOUT = V+ www.national.com 0.005 6 0.4 V 1 A Parameter Conditions Min (Note 9) Typical (Note 8) Max (Note 9) Units V DIGITAL INPUTS: A0 and A1 VIN(1) VIM VIN(0) Logical "1" Input Voltage 0.90 x V+ 5.5 Logical Middle Input Voltage 0.43 x V+ 0.57 x V+ GND 0.05 0.10 x V+ V Logical "0" Input Voltage SERIAL BUS INPUTS: SCL and SDA VIN(1) Logical "1" Input Voltage 0.7 x V+ 5.5 v VIN(0) Logical "0" Input Voltage GND 0.05 0.3 x V+ V VHYST Hysteresis Voltage V+ = +3.3V 0.67 V V+ = +5.5V 1.45 V - 0.005 A ALL DIGITAL INPUTS: SCL, SDA, A0, A1 IIN(1) Logical "1" Input Current VIN = V+ IIN(0) Logical "0" Input Current VIN = 0 VDC CIN Digital Input Capacitance -1 0.005 20 7 1 A pF www.national.com ADC128D818 Symbol ADC128D818 13.0 AC Electrical Characteristics The following specifications apply for +3.0 VDC V+ +5.5 VDC , unless otherwise specified. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = 25C. Symbol Parameter Conditions Min (Note 9) Typical (Note 8) Max (Note 9) Units 100 s SERIAL BUS TIMING CHARACTERISTICS t1 SCL (Clock) Period 2.5 t2 Data In Setup Time to SCL High 100 ns t3 Data Out Stable After SCL Low 0 ns t4 SDA Low Setup Time to SCL Low (start) 100 ns t5 SDA High Hold Time After SCL High (stop) 100 ns tTIMEOUT SCL or SDA time low for I2C bus reset 25 35 ms 30096326 FIGURE 1. Serial Bus Timing Diagram Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The guaranteed specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test conditions. Note 2: All voltages are measured with respect to GND, unless otherwise specified. Note 3: If the input voltage at any pin exceeds the power supply ( that is, VIN < GND or VIN > V +) but is less than the absolute maximum ratings, then the current at that pin should be limited to 5mA. The 30 mA maximum package input current rating limits the number of pins that can safely exceed the power supply with an input current of 5mA to six pins. Parasitic components and/or ESD protection circuitry are shown in the Pin Descriptions table. Note 4: The maximum power dissipation must be derated at elevated temperatures and is dictated by TJMAX, JA and the ambient temperature, TA. The maximum allowable power dissipation at any temperature is PD = (TJMAX - T A) / JA. Note 5: For the given JA, the device is on a 2-layer printed circuit board with 1 oz. copper foil and no airflow. Note 6: Human body model (HBM) is a charged 100pF capacitor discharged into a 1.5k resistor. Machine model (MM) is a charged 200pF capacitor discharged directly into each pin. Charged Device Model (CDM) simulates a pin slowly acquiring charge (such as from a device sliding down the feeder in an automated assembler) then rapidly being discharged. Note 7: Each input and output is protected by an ESD structure to GND, as shown in the Pin Descriptions table. Input voltage magnitude up to 0.3V above V+ or 0.3V below GND will not damage the ADC128D818. There are diodes that exist between some inputs and the power supply rails. Errors in the ADC conversion can occur if these diodes are forward biased by more than 50mV. As an example, if V+ is 4.50 VDC, INx (where 0 x 7) must be 4.55 VDC to ensure accurate conversions. Note 8: Typicals are at TJ = TA = 25C and represent most likely parametric norm. Note 9: Limits are guaranteed to National's AOQL (Average Outgoing Quality Level). Note 10: Limit is guaranteed by characterization. Note 11: TUE (Total Unadjusted Error) includes Offset, Gain and Linearity errors of the ADC. Note 12: The range is up to 7/8 of full scale. Note 13: Limit is guaranteed by design. Note 14: Timing specifications are tested at the Serial Bus Input logic levels: VIN(0) = 0.3 x V+ for a falling edge and VIN(1) = 0.7 x V+ for a rising edge if the SCL and SDA edge rates are similar. ---- www.national.com 8 The following typical performance plots apply for the internal VREF = 2.56V, V+ = 3.3V, Pseudo-Differential connection, unless otherwise specified. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = 25C. (Note 14) TUE vs. Code TUE vs. Code (External VREF = 1.25V) 30096346 30096347 TUE vs. Code (External VREF = 2.56V) TUE vs. Code (External VREF = 5V, V+ = 5V) 30096348 30096349 INL vs. Code (External VREF = 1.25V for 1 Unit) INL vs. Code (External VREF = 1.25V for 28 Units) 30096350 30096371 9 www.national.com ADC128D818 14.0 Typical Performance Characteristics ADC128D818 INL vs. Code (External VREF = 2.56V for 1 Unit) INL vs. Code (External VREF = 2.56V for 28 Units) 30096351 30096372 INL vs. Code (External VREF = 5V, V+ = 5V for 1 Unit) INL vs. Code (External VREF = 5V, V+ = 5V for 28 Units) 30096352 30096373 DNL vs. Code (External VREF = 2.56V for 1 Unit) DNL vs. Code (External VREF = 2.56V for 28 Units) 30096354 www.national.com 30096355 10 ADC128D818 Offset Error vs. V+ Offset Error vs. Temperature 30096356 30096358 Gain Error vs. V+ Gain Error vs. Temperature 30096360 30096362 I+ vs. Temperature I+ vs. V+ Typical 30096364 30096365 11 www.national.com ADC128D818 I+ vs. V+ for Voltage Conversion I+ vs. V+ for Temperature Conversion 30096367 30096366 I+ vs. V+ in Shutdown Mode I+ vs. V+ in Deep Shutdown Mode 30096368 www.national.com 30096369 12 15.1 GENERAL DESCRIPTION The ADC128D818 provides 8 analog inputs, a temperature sensor, a delta-sigma ADC, an external or internal VREF option, and WATCHDOG registers on a single chip. An I2C Serial Bus interface is also provided. The ADC128D818 can perform voltage and temperature monitoring for a variety of systems. The ADC128D818 continuously converts the voltage input to 12-bit resolution with an internal VREF of 0.625mV LSb (Least Significant bit) weighting, yielding input range of 0V to 2.56V. There is also an external VREF option that ranges from 1.25V to V+. The analog inputs are intended to be connected to several power supplies present in a variety of systems. Eight inputs can be configured for single-ended and/or pseudo-differential channels. Temperature can be converted to a 9-bit two's complement word with resolutions of 0.5C per LSb. The ADC128D818 provides a number of internal registers. These registers are summarized in the "ADC128D818 Internal Registers" section. The ADC128D818 supports Standard Mode (Sm, 100kbits/s) and Fast Mode (Fm, 400kbits/s) I2C interface modes of operation. ADC128D818 includes an analog filter on the I2C digital control lines that allows improved noise immunity. The device also supports TIMEOUT reset function on SDA and SCL to prevent I2C bus lock-up. Two tri-level address pins allow up to 9 devices on a single I2C bus. At start-up, ADC128D818 cycles through each measurement in sequence and continuously loops through the sequence based on the Conversion Rate Register (address 07h) setting. Each measured value is compared to values stored in the Limit Registers (addresses 2Ah - 39h). When the measured value violates the programmed limit, the ADC128D818 will set a corresponding interrupt bit in the Interrupt Status Registers (address 01h). An interrupt output pin, INT, is also available and fully programmable. 15.4 ANALOG INPUTS (IN0 - IN7) The ADC128D818 allows up to 8 single-ended inputs or 4 pseudo-differential inputs as selected by the modes of operation. The input types are described in the next subsections. 15.4.1 Single-Ended Input ADC128D818 allows a maximum of 8 single-ended inputs, where the source's voltage is connected to INx (0 x 7). The source's ground should be connected to ADC128D818's GND pin. In theory, INx can be of any value between 0V and (VREF-3LSb/2), where LSb = VREF/212. To use the device single-endedly, refer to the "Modes of Operation" section and to bits [2:1] of the Advanced Configuration Register (address 0Bh). Figure 2 shows the appropriate configuration for a single-ended connection. 30096331 FIGURE 2. Single-Ended Configuration 15.4.2 Pseudo-Differential Input Pseudo-differential mode is defined as the positive input voltage applied differentially to the ADC128D818, as shown in Figure 3. The input that is digitized is (VIN = IN+ - IN-), where (IN+ - IN-) is (IN0-IN1), (IN3-IN2), (IN4-IN5), or (IN7-IN6). Be aware of this input configuration because the order is swapped. In theory, VIN can be of any value between 0V and (VREF-3LSb/2),where LSb = VREF/212. By using this pseudo-differential input, small signals common to both inputs are rejected. Thus, operation with a pseudodifferential input signal will provide better performance than with a single-ended input. Refer to the "Modes of Operation" section for more information. 15.2 SUPPLY VOLTAGE (V+) The ADC128D818 operates with a supply voltage, V+, that has a range between +3.0V to +5.5V. Care must be taken to bypass this pin with a parallel combination of 1 F (electrolytic or tantalum) capacitor and 0.1 F (ceramic) bypass capacitor. 15.3 VOLTAGE REFERENCES (VREF) The reference voltage (VREF) sets the analog input range. The ADC128D818 has two options for setting VREF. The first option is to use the internal VREF, which is equal to 2.56V. The second option is to source VREF externally via pin 1 of ADC128D818. In this case, the external VREF will operate in the range of 1.25V to V+. The default VREF selection is the internal VREF. If the external VREF is preferred, use the Advanced Configuration Register (address 0Bh) to change this setting. VREF source must have a low output impedance and needs to be bypassed with a minimum capacitor value of 0.1 F. A larger capacitor value of 1 F placed in parallel with the 0.1 F is preferred. VREF of the ADC128D818, like all ADC converters, does not reject noise or voltage variations. Keep this in mind if VREF is derived from the power supply. Any noise and/or ripple from the supply that is not rejected by the external reference circuitry will appear in the digital results. 30096332 FIGURE 3. Pseudo-Differential Configuration 13 www.national.com ADC128D818 The use of a reference source is recommended. The LM4040 and LM4050 shunt reference families as well as the LM4120 and LM4140 series reference families are excellent choices for a reference source. 15.0 Functional Description ADC128D818 the Advanced Configuration Register (address 0Bh, bits [2:1]). 15.4.3 Modes of Operation ADC128D818 allows 4 modes of operation, as summarized in the following table. Set the desired mode of operation using TABLE 3. Modes of Operation Ch. Mode 0 Mode 1 Mode 2 Mode 3 1 IN0 IN0 IN0 (+) & IN1 (-) IN0 2 IN1 IN1 IN3 (+) & IN2 (-) IN1 IN2 IN4 (+) & IN5 (-) IN2 IN3 IN7 (+) & IN6 (-) 3 4 IN2 IN3 IN3 5 IN4 IN4 IN4 (+) & IN5 (-) 6 IN5 IN5 IN7 (+) & IN6 (-) 7 IN6 IN6 8 nc* IN7 Local Temp Yes No Yes Yes * nc = No Connect the pseudo-differential configuration. In theory, VIN can be of any value between 0V and (VREF-3LSb/2). Any VIN value outside of this range will produce a digital output code of 0 or 4095. Figure 4 shows a theoretical plot of DOUT vs. VIN and some sample DOUT calculation using the equation above. 15.5 DIGITAL OUTPUT (DOUT) The digital output code for a 12-bit ADC can be calculated as: DOUT = [VIN / VREF] x 212 For the above equation, VIN = INx - GND, where 0 x 7, for the single-ended configuration, and VIN = (IN+ - IN-) for 30096333 FIGURE 4. DOUT vs VIN for a 12-bit ADC assuming VREF = 2.56V. www.national.com 14 30096345 FIGURE 5. I+ Equation Where "a" is the number of local temperature available, and "b" is the number of ENABLED voltage channel. Each mode of operation has a different "a" and "b" values. The following table shows the value for "a" and the maximum value for "b" for each mode. TABLE 4. "a" and "b" Values 15 a b (Max) Mode 0 1 7 Mode 1 0 8 Mode 2 1 4 Mode 3 1 6 www.national.com ADC128D818 15.6 POWER MANAGEMENT To understand the average supply current (I+), the conversion rates must be introduced. ADC128D818 has three types of conversion rates: Continuous Conversion Mode, Low Power Conversion Mode, and One Shot Mode. In the Low Power Conversion Mode, the device converts all of the enabled channels then enters shutdown mode; this process takes approximately 728 ms to complete. (More information on the conversion rate will be discussed in the "Conversion Rate Register (address 07h)" and "One-Shot Register (address 09h)" sections). Each type of conversion produces a different average supply current. The supply current for a voltage conversion will be referred to as I+_VOLTAGE, a temperature conversion as I+_TEMP, and the shutdown mode as I+_SHUTDOWN. These values can be obtained from Typical Performance Characteristics plots. In general, I+ is the average supply current while ADC128D818 is operating in the Low Power Conversion Mode with all of the available channels enabled. Its plot can be seen in the "Typical Performance Characteristic" section and its equation is shown below. ADC128D818 I2C bus. Examples to set each address bit low, high, or to midscale can be found in the "Example Applications" section. The Serial Bus Address can be set as follows: 15.7 INTERFACE The Serial Bus control lines include the SDA (serial data), SCL (serial clock), and A0-A1 (Serial Bus Address) pins. The ADC128D818 can only operate as a slave. The SCL line only controls the serial interface, and all of other clock functions within ADC128D818 are done with a separate asynchronous internal clock. When the Serial Bus Interface is used, a write will always consists of the ADC128D818 Serial Bus Address byte, followed by the Register Address byte, then the Data byte. Figure 6 and Figure 7 are two examples showing how to write to the ADC128D818. There are two cases for a read: 1. If the Register Address is known to be at the desired address, simply read the ADC128D818 with the Serial Bus Address byte, followed by the Data byte read from the ADC128D818. Examples of this type of read can be seen in Figure 8 and Figure 9. 2. If the Register Address value is unknown, write to the ADC128D818 with the Serial Bus Address byte, followed by the desired Register Address byte. Then restart the Serial Communication with a Read consisting of the Serial Bus Address byte, followed by the Data byte read from the ADC128D818. See Figure 10 and Figure 11 for examples of this type of read. The Serial Bus Address can be found in the next section, and the Register Address can be found in the "Register Map" section. For more information on the I2C Interface, refer to NXP's "I2C-Bus Specification and User Manual", rev. 03. TABLE 5. Serial Bus Address Table Serial Bus Address Serial Bus [A6][A5][A4]...[A0] Address (hex) A1 A0 LOW LOW 001_1101b 1Dh LOW MID 001_1110b 1Eh LOW HIGH 001_1111b 1Fh MID LOW 010_1101b 2Dh MID MID 010_1110b 2Eh MID HIGH 010_1111b 2Fh HIGH LOW 011_0101b 35h HIGH MID 011_0110b 36h HIGH HIGH 011_0111b 37h 15.7.2 Timeout The ADC128D818 I2C state machine resets to its idle state if either SCL or SDA is held low for longer than 35ms. This feature also ensures that ADC128D818 will automatically release SDA after driving it low continuously for 25-35ms, hence preventing I2C bus lock-up. The TIMEOUT feature should not be used when the device is operating in deep shutdown mode. 15.7.1 Serial Bus Address There are nine different configurations for the ADC128D818 Serial Bus Address, thus nine devices are allowed on a single 15.7.3 Example Writes and Reads 30096309 FIGURE 6. Serial Bus Interface Write Example 1 - Internal Address Register Set Only. www.national.com 16 ADC128D818 30096308 FIGURE 7. Serial Bus Interface Write Example 2 - Internal Address Register Set with Data Byte Write. 30096310 FIGURE 8. Serial Bus Interface Read Example 1 - Single Byte Read with Preset Internal Address Register. 30096322 FIGURE 9. Serial Bus Interface Read Example 2 - Double Byte Read with Preset Internal Address Register. 17 www.national.com ADC128D818 30096324 FIGURE 10. Serial Bus Interface Read Example 3 - Single Byte Read with Internal Address Set using a Repeat Start. 30096323 FIGURE 11. Serial Bus Interface Read Example 4 - Double Byte Read with Internal Address Set using a Repeat Start. www.national.com 18 ADC128D818 15.8 USING THE ADC128D818 15.8.1 ADC128D818 Internal Registers TABLE 6. ADC128D818 Internal Registers Register Name Configuration Register Read/ Write Register Address (hex) Default Value [7:0] R/W 00h 0000_1000 Provides control and configuration 8-bit 8-bit Register Description Register Format Interrupt Status Register R 01h 0000_0000 Provides status of each WATCHDOG limit or interrupt event Interrupt Mask Register R/W 03h 0000_0000 Masks the interrupt status from propagating to INT 8-bit Conversion Rate Register R/W 07h 0000_0000 Controls the conversion rate 8-bit 8-bit Channel Disable Register One-Shot Register Deep Shutdown Register Advanced Configuration Register R/W 08h 0000_0000 Disables conversion for each voltage or temperature channel W 09h 0000_0000 Initiates a single conversion of all enabled channels 8-bit R/W 0Ah 0000_0000 Enables deep shutdown mode 8-bit 8-bit R/W 0Bh 0000_0000 Selects internal or external VREF and modes of operation Busy Status Register R 0Ch 0000_0010 Reflects the ADC128D818 'Busy' and 'Not Ready' statuses 8-bit Channel Readings Registers R 20h - 27h --- Report channels (voltage or temperature) readings 16-bit R/W 2Ah - 39h --- Set the limits for the voltage and temperature channels 8-bit Manufacturer ID Register R 3Eh 0000_0001 Reports the manufacturer's ID 8-bit Revision ID Register R 3Fh 0000_1001 Reports the revision's ID 8-bit Limit Registers the registers to their default values. These default values are shown in the table above or in the "Register Map" section. Registers whose default values are not shown have power on conditions that are indeterminate. 15.8.2 Quick Start 1. Power on the device, then wait for at least 33ms. 2. Read the Busy Status Register (address 0Ch). If the 'Not Ready' bit = 1, then increase the wait time until 'Not Ready' bit = 0 before proceeding to the next step. 3. Program the Advanced Configuration Register (address 0Bh): a. Choose to use the internal or external VREF (bit 0). b. Choose the mode of operation (bits [2:1]). 4. Program the Conversion Rate Register (address 07h). 5. Choose to enable or disable the channels using the Channel Disable Register (address 08h). 6. Using the Interrupt Mask Register (address 03h), choose to mask or not to mask the interrupt status from propagating to the interrupt output pin, INT. 7. Program the Limit Registers (addresses 2Ah - 39h). 8. Set the `START' bit of the Configuration Register (address 00h, bit 0) to 1. 9. Set the 'INT_Clear' bit (address 00h, bit 3) to 0. If needed, program the 'INT_Enable' bit (address 00h, bit 1) to 1 to enable the INT output. The ADC128D818 then performs a round-robin monitoring of enabled voltage and temperature channels. The sequence of items being monitored corresponds to locations in the Channel Readings Registers (except for the temperature reading). Detailed descriptions of the register map can be found at the end of this datasheet. 15.8.4 Configuration Register (address 00h) The Configuration Register (address 00h) provides all control to the ADC128D818. After POR, the 'START' bit (bit 0) is set low and the 'INT_Clear' bit (bit 3) is set high. The Configuration Register has the ability to start and stop the ADC128D818, enable and disable the INT output, and set the registers to their default values. * Bit 0, `START', controls the monitoring loop of the ADC128D818. After POR, set this bit high to start conversion. Setting this bit low stops the ADC128D818 monitoring loop and puts the ADC128D818 in shutdown mode; thus, reducing power consumption. Even though this bit is set low, serial bus communication is possible with any register in the ADC128D818. After an interrupt occurs, the INT pin will not be cleared if the user sets this bit low. * Bit 1, 'INT_Enable', enables the interrupt output pin, INT, when this bit is set high. * Bit 3, 'INT_Clear', clears the interrupt output pin, INT, when this bit is set high. When this bit is set high, the ADC128D818 monitoring function will stop. The content of the Interrupt Status Register (address 01h) will not be affected. * Bit 7, `INITIALIZATION', accomplishes the same function as POR, that is, it initializes some of the registers to their default values. This bit automatically clears after being set high. Setting this bit high, however, does not reset the Channel Readings Registers (addresses 20h - 27h) and 15.8.3 Power On Reset (POR) When power is first applied, the ADC128D818 performs a power on reset (POR) on several of its registers, which sets 19 www.national.com ADC128D818 the Limit Registers (addresses 2Ah - 39h). These registers will be indeterminate immediately after power on. If the Channel Readings Registers contain valid conversion results and/or the Limit Registers have been previously set, they will not be affected by this bit. 15.8.8 One-Shot Register (address 09h) The One-Shot register is used to initiate a single conversion and comparison cycle when the device is in shutdown mode or deep shutdown mode, after which the device returns to the respective mode it was in. The obvious advantage of using this mode is lower power consumption because the device is operating in shutdown or deep shutdown mode. This register is not a data register, and it is the write operation that causes the one-shot conversion. The data written to this address is irrelevant and is not stored. A zero will always be read from this register. 15.8.5 Interrupt Status Register (address 01h) Each bit in this read-only register indicates whether the voltage reading > the voltage high limit or the voltage low limit, or the temperature reading > the temperature high limit. For example, if "IN0 High Limit" register (address 2Ah) were set to 2V and if IN0 reading (address 20h) were 2.56V, then bit 'IN0 Error' would be 1, indicating that the voltage high limit has been exceeded. 15.8.9 Deep Shutdown Register (address 0Ah) The ADC128D818 can be placed in deep shutdown mode, thus reducing more power consumption. The procedures for deep shutdown entrance are: 1. Enter shutdown by setting the `START' bit of the "Configuration Register' (address 00h, bit 0) to 0. 2. Enter deep shutdown by setting the `DEEP SHUTDOWN' bit (address 0Ah, bit 0) to 1. 3. A one-shot conversion can be triggered by writing any values to register address 09h. Deep Shutdown Exit Procedure: 1. Set the `DEEP SHUTDOWN' bit to 0. 15.8.6 Interrupt Mask Register (address 03h) This register masks the interrupt status from propagating to the interrupt output pin, INT. For example, if bit 'IN0 Mask' = 1, then the interrupt output pin, INT, would not be pulled low even if an error event occurs at IN0. 15.8.7 Conversion Rate Register (address 07h) There are three options for controlling the conversion rate. The first option is called the Low Power Conversion Mode, where the device converts all of the enabled channels then enters shutdown mode. This process takes approximately 728 ms to complete. The second option is the Continuous Conversion Mode, where the device continuously converts the enabled channels, thus never entering shutdown mode. A voltage conversion takes 12.2 ms, and a temperature conversion takes 3.6 ms. For example, if operating in mode 2 and three voltage channels were enabled, then each round-robin monitor would take 40.2 ms (3 x 12.2ms + 3.6ms) to complete. Use the "Channel Disable Register" (address 08h) to disable the desired channel(s). The third option is called the On-Shot mode, which will be discussed in the next subsection. www.national.com 15.8.10 Channel Readings Registers (addresses 20h 27h) The channel conversion readings are available in registers 20h to 27h. Each register is 16-bit wide to accommodate the 12-bit voltage reading or 9-bit temperature reading. Conversions can be read at any time and will provide the result of the last conversion. If a conversion is in progress while a communication is started, that conversion will be completed, and the Channel Reading Registers will not be updated until the communication is complete. 20 30096320 (Non-Linear Scale for Clarity) FIGURE 12. 9-bit Temperature-to-Digital Transfer Function Binary [MSb...LSb] Decimal Hex +125C 0 _1111_1010 250 0_FA +25C 0_0011_0010 50 0_32 +0.5C 0_0000_0001 1 0_01 +0C 0_0000_0000 0 0_00 > Thot, an interrupt occurs. How this interrupt occurs will be explained in the "Temperature Interrupt" section. Each temperature limit is represented by an 8-bit, two's complement word with an LSb (Least Significant bit) equal to 1C. The table below shows some sample temperatures that can be programmed to the Temperature Limit Registers. In general, use the following equations to calculate the digital code that represents the desired temperature limit: -0.5C 1_1111_1111 511 1_FF If Temp Limit (C) >= 0: Digital Code (dec) = Temp Limit(C) -25C 1_1100_1110 462 1_CE -40C 1_1011_0000 432 1_B0 If Temp Limit (C) < 0: Digital Code (dec) = 28 - |Temp Limit (C)| Temp Digital Output (DOUT) In general, the easiest way to calculate the temperature (C) is to use the following formulas: Temp Limit If DOUT[MSb] = 0: +Temp(C) = DOUT(dec) / 2 Digital Code Binary [MSb...LSb] Decimal Hex +125C 0111_1101 125 7D If DOUT[MSb] = 1: -Temp(C) = [29 - DOUT(dec)] / 2 +25C 0001_1001 25 19 15.9.1 Temperature Limits One of the ADC128D818 features is monitoring the temperature reading. This monitoring is accomplished by setting a temperature limit to the Temperature High Limit Register (Thot , address 38h) and Temperature Hysteresis Limit Register (Thot_hyst, address 39h). When the temperature reading +1.0C 0000_0001 1 01 +0C 0000_0000 0 00 -1.0C 1111_1111 255 FF -25C 1110_1111 231 E7 -40C 1101_1000 216 D8 21 www.national.com ADC128D818 27h). This register is 16-bit wide, and thus, all 9 bits of the temperature reading can be read using a double byte read (Figure 9 or Figure 11). The following figure and the table below it show the theoretical output code (DOUT) vs. temperature and some typical temperature-to-code conversions. 15.9 TEMPERATURE MEASUREMENT SYSTEM The ADC128D818 delta-VBE type temperature sensor and delta-sigma ADC perform 9-bit two's-complement conversions of the temperature. This temperature reading can be obtained at the Temperature Reading Register (address ADC128D818 15.10 INTERRUPT STRUCTURE 30096318 FIGURE 13. Interrupt Structure Figure 13 shows the ADC128D818's Interrupt Structure. Note that the number next to each bit name represents its register address and bit number. For example, 'INT_Clear' (00h[3]) refers to bit 3 of register address 00h. Another method to clear the interrupt output pin, INT, is setting 'INT_Clear' bit (address 00h, bit 3) = 1. When this bit is high, the ADC128D818 round-robin monitoring loop will stop. 15.10.3 Temperature Interrupt One of the ADC128D818 features is monitoring the temperature reading. This monitoring is accomplished by setting a temperature limit to the Temperature High Limit Register (Thot , address 38h) and Temperature Hysteresis Limit Register (Thot_hyst, address 39h). These limit registers have an interrupt mode, shown in Figure 14, that operates the the following way: if the temperature reading > Thot, an interrupt will occur and will remain active indefinitely until reset by reading the Interrupt Status Register (address 01h) or cleared by the 'INT_Clear' bit. Once an interrupt event has occurred by crossing Thot, then reset, an interrupt will occur again once the next temperature conversion has completed. The interrupts will continue to occur in this manner until the temperature reading is Thot_hyst and a read of the Interrupt Status Register has occurred. 15.10.1 Interrupt Output (INT) ADC128D818 generates an interrupt as a result of each of its internal WATCHDOG registers on the voltage and temperature channels. In general, INT becomes active when all three scenarios, as depicted in Figure 13, occur: 1. 'INT_Clear' (00h[3]) = 0. 2. 'INT_Enable' (00h[1]) = 1 to enable interrupt output. 3. The voltage reading > the voltage high limit or the voltage low limit, or the temperature reading > Thot. 15.10.2 Interrupt Clearing Reading the Interrupt Status Register (addresses 01h) will output the contents of the register and clear the register. When the Interrupt Status Register clears, the interrupt output pin, INT, also clears until this register is updated by the roundrobin monitoring loop. 30096317 FIGURE 14. Temperature Response Structure (Assuming the interrupt output pin, INT, is reset before the next temperature reading) www.national.com 22 ADC128D818 15.11 EXAMPLE APPLICATIONS 15.11.1 General Voltage Monitoring 30096341 FIGURE 15. Typical Analog Input Application A typical application for ADC128D818 is voltage monitoring. In this application, the inputs would most often be connected to linear power supplies of 2.5V, 3.3V, 5V and 12V inputs. These inputs should be attenuated with external resistors to any desired value within the input range. The attenuation is done with resistors R1 and R2 for the positive single-ended voltage, and R3 and R4 for the positive pseudo-differential voltage. A typical single-ended application might select the input voltage divider to provide 1.9V at the analog input of the ADC128D818. This is sufficiently high for good resolution of the voltage, yet leaves headroom for upward excursions from the supply of about 25%. To simplify the process of resistor selection, set the value of R2 first. Select a value for R2 between 10 kOhm and 100 kOhm. This is low enough to avoid errors due to input leakage currents yet high enough to protect both the inputs under and overdrive conditions as well as minimize loading of the source. Finally, calculate R1 to provide a 1.9V input using simple voltage divider derived formula: Care should be taken to bypass V+ with decoupling 0.1 F ceramic capacitor and 1 F tantalum capacitor. If using the external reference option, VREF should be connected to a voltage reference, such as the LM4140, and should also be decoupled to the ground plane by a 0.1 F ceramic capacitor and a 1 F tantalum capacitor. For both supplies, the 0.1 F capacitor should be located as close as possible to the ADC128D818. Since SDA, SCL, and INT are open-drain pins, they should have external pull-up resistors to ensure that the bus is pulled high until a master device or slave device sinks enough current to pull the bus low. A typical pull-up resistor, R, ranges from 1.1 kOhm to 10 kOhm. Refer to NXP's "I2C-Bus Specification and User Manual" for more information on sizing R. Because there are two tri-level address pins (A0 and A1), up to 9 devices can share the same I2C bus. A trick to set these serial addresses utilizes four GPO (general purpose output) pins from the master device as shown in the example diagram. A table showing how to program these GPO pins can be seen below. R1 = [(VS1 - VIN2) / VIN2 ] x R2 23 www.national.com ADC128D818 TABLE 7. Setting Serial Bus Address using GPO A1 A0 GPO1 GPO2 GPO3 GPO4 LOW LOW Z LOW Z LOW LOW MID Z LOW HIGH LOW LOW HIGH Z LOW HIGH Z MID LOW HIGH LOW Z LOW MID MID HIGH LOW HIGH LOW MID HIGH HIGH LOW HIGH Z HIGH LOW HIGH Z Z LOW HIGH MID HIGH Z HIGH LOW HIGH HIGH HIGH Z HIGH Z Z = high impedance 15.11.2 Voltage Monitoring for Power Supplies 30096342 FIGURE 16. Power Supply Application Figure 16 shows a more complete systems application using a DC/DC converter. Such configuration can be used in a power supply application. The point to make with this example diagram is the Serial Bus Address connections. The previous example shows A0 and A1 connected to four GPOs, but this example shows a simpler A0 and A1 connection using two resistor dividers. This connection accomplishes the same www.national.com goal as the GPO connection, that is, it can set A0 and A1 high, low, or to midscale. For example, to set A0 high, don't populate RB_bottom; to set A0 low, don't populate RB_top; and to set A0 to midscale, leave RB_top and RB_bottom as is and set them equal to each other. A typical RB value ranges from 1 kOhm to 10 kOhm. 24 ADC128D818 15.11.3 Temperature Sensors 30096343 FIGURE 17. Temperature Sensor Applications An external temperature sensor can be connected to any of ADC128D818's eight single-ended input for additional temperature sensing. One such temperature sensor can be National's LM94022, a precision analog temperature sensor with selectable gains. The application diagram shows LM94022's gains (GS1 and GS0) both grounded indicating the lowest gain setting. Four possible gains can be set using these GS1 and GS0 pins. According to the LM94022 datasheet, the voltage-to-temperature output plot can be determined using the method of linear approximation as follows: Where V is in mV, T is in C, V1 and T1 are the coordinates of the lowest temperature, and T2 and V2 are the coordinates of the highest temperature. For example, to determine the equation of a line over a temperature range of 20C to 50C, first find V1 and V2 relative to those temperatures, then use the above equation to find the transfer function. V - 925 mV = (760 mV - 925 mV) / (50C - 20C) x (T - 20C) V = (-5.50 mV /C) x T + 1035 mV For more information and explanation of this example, refer to the LM94022 datasheet. V - V1 = (V2 - V1) / (T2 - T1) x (T - T1) 25 www.national.com ADC128D818 15.11.4 Bridge Sensors 30096344 FIGURE 18. Bridge Sensor Application ADC128D818 is perfect for transducer applications such as pressure sensors. These sensors measure pressure of gases or liquids and produce a pressure-equivalent voltage at their outputs. Figure 18 shows a typical connection of a pressure sensor, represented by the bridge sensor. Most pressure sensor has a low sensitivity characteristic, which means its output is typically in the millivolts range. Because of that reason, an op-amp, such as an instrumentation amplifier, can be used for the gain stage. The positive aspect of this configuration is its ratiometric connection. A ratiometric connection is when the ADC's VREF and GND are connected to the bridge sensor's voltage refer- www.national.com ences. With a ratiometric configuration, external VREF accuracy can be ignored. 15.11.5 Layout and Grounding Analog inputs will provide best accuracy when referred to the GND pin or a supply with low noise. A separate, lowimpedance ground plane for analog ground, which provides a ground point for the voltage dividers and analog components, will provide best performance but is not mandatory. Analog components such as voltage dividers should be located physically as close as possible to the ADC128D818. 26 ADC128D818 15.12 REGISTER MAP 15.12.1 ADC128D818 Internal Registers TABLE 8. ADC128D818 Internal Registers Register Name Configuration Register Read/ Write Register Address (hex) Default Value [7:0] R/W 00h 0000_1000 Provides control and configuration 8-bit 8-bit Register Format Register Description Interrupt Status Register R 01h 0000_0000 Provides status of each WATCHDOG limit or interrupt event Interrupt Mask Register R/W 03h 0000_0000 Masks the interrupt status from propagating to INT 8-bit Conversion Rate Register R/W 07h 0000_0000 Controls the conversion rate 8-bit 8-bit R/W 08h 0000_0000 Disables conversion for each voltage or temperature channel W 09h 0000_0000 Initiates a single conversion of all enabled channels 8-bit Deep Shutdown Register R/W 0Ah 0000_0000 Enables deep shutdown mode 8-bit Advanced Configuration Register R/W 0Bh 0000_0000 Selects internal or external VREF and modes of operation 8-bit Busy Status Register R 0Ch 0000_0010 Reflects ADC128D818 'Busy' and 'Not Ready' statuses 8-bit Channel Readings Registers R 20h - 27h --- Report the channels (voltage or temperature) readings 16-bit R/W 2Ah - 39h --- Set the limits for the voltage and temperature channels 8-bit Manufacturer ID Register R 3Eh 0000_0001 Reports the manufacturer's ID 8-bit Revision ID Register R 3Fh 0000_1001 Reports the revision's ID 8-bit Channel Disable Register One-Shot Register Limit Registers 15.12.2 Configuration Register -- Address 00h Default Value [7:0] = 0000_1000 binary Bit Bit Name Read/Write Bit(s) Description ALL MODES 0 Start Read/Write 0: ADC128D818 in shutdown mode 1: Enable startup of monitoring operations 1 INT_Enable Read/Write 1: Enable the interrupt output pin, INT 2 Reserved Read Only 3 INT_Clear Read/Write 4 Reserved Read Only 5 Reserved Read Only 6 Reserved Read Only 7 Initialization Read/Write 1: Clear the interrupt output pin, INT, without affecting the contents of Interrupt Status Registers. When this bit is set high, the device stops the round-robin monitoring loop. 1: Restore default values to the following registers: Configuration, Interrupt Status, Interrupt Mask, Conversion Rate, Channel Disable, One-Shot, Deep Shutdown, Advanced Configuration, Busy Status, Channel Readings, Limit, Manufacturer ID, Revision ID. This bit clears itself 27 www.national.com ADC128D818 15.12.3 Interrupt Status Register -- Address 01h Default Value [7:0] = 0000_0000 binary Bit Bit Name Read/Write Bit(s) Description 0 IN0 Error Read Only 1: A High or Low limit has been exceeded 1 IN1 Error Read Only 1: A High or Low limit has been exceeded 2 IN2 Error Read Only 1: A High or Low limit has been exceeded 3 IN3 Error Read Only 1: A High or Low limit has been exceeded 4 IN4 Error Read Only 1: A High or Low limit has been exceeded 5 IN5 Error Read Only 1: A High or Low limit has been exceeded 6 IN6 Error Read Only 1: A High or Low limit has been exceeded 7 Hot Temperature Error Read Only 1: A High limit has been exceeded 0 IN0 Error Read Only 1: A High or Low limit has been exceeded 1 IN1 Error Read Only 1: A High or Low limit has been exceeded 2 IN2 Error Read Only 1: A High or Low limit has been exceeded 3 IN3 Error Read Only 1: A High or Low limit has been exceeded 4 IN4 Error Read Only 1: A High or Low limit has been exceeded 5 IN5 Error Read Only 1: A High or Low limit has been exceeded 6 IN6 Error Read Only 1: A High or Low limit has been exceeded 7 IN7 Error Read Only 1: A High or Low limit has been exceeded 0 IN0(+) & IN1(-) Error Read Only 1: A High or Low limit has been exceeded 1 IN3(+) & IN2(-) Error Read Only 1: A High or Low limit has been exceeded 2 IN4(+) & IN5(-) Error Read Only 1: A High or Low limit has been exceeded 3 IN7(+) & IN6(-) Error Read Only 1: A High or Low limit has been exceeded 4 Reserved Read Only 5 Reserved Read Only 6 Reserved Read Only 7 Hot Temperature Error Read Only 1: A High limit has been exceeded 0 IN0 Error Read Only 1: A High or Low limit has been exceeded 1 IN1 Error Read Only 1: A High or Low limit has been exceeded 2 IN2 Error Read Only 1: A High or Low limit has been exceeded 3 IN3 Error Read Only 1: A High or Low limit has been exceeded 4 IN4(+) & IN5(-) Error Read Only 1: A High or Low limit has been exceeded 5 IN7(+) & IN6(-) Error Read Only 1: A High or Low limit has been exceeded 6 Reserved Read Only 7 Hot Temperature Error Read Only MODE 0 MODE 1 MODE 2 MODE 3 www.national.com 1: A High limit has been exceeded 28 ADC128D818 15.12.4 Interrupt Mask Register -- Address 03h Default Value [7:0] = 0000_0000 binary Bit Bit Name Read/Write Bit(s) Description 0 IN0 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 1 IN1 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 2 IN2 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 3 IN3 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 4 IN4 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 5 IN5 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 6 IN6 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 7 Temperature Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 0 IN0 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 1 IN1 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 2 IN2 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 3 IN3 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 4 IN4 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 5 IN5 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 6 IN6 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 7 IN7 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 0 IN0(+) & IN1(-) Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 1 IN3(+) & IN2(-) Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 2 IN4(+) & IN5(-) Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 3 IN7(+) & IN6(-) Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 4 Reserved Read Only 5 Reserved Read Only 6 Reserved Read Only 7 Temperature Mask Read/Write MODE 0 MODE 1 MODE 2 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 29 www.national.com ADC128D818 Bit Bit Name Read/Write Bit(s) Description 0 IN0 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 1 IN1 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 2 IN2 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 3 IN3 Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 4 IN4(+) & IN5(-) Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 5 IN7(+) & IN6(-) Mask Read/Write 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 6 Reserved Read Only 7 Temperature Mask Read/Write MODE 3 1: Mask the corresponding interrupt status from propagating to the interrupt output pin, INT 15.12.5 Conversion Rate Register -- Address 07h Default Value [7:0] = 0000_0000 binary Bit 0 1-7 Bit Name Read/Write Bit(s) Description Conversion Rate Read/Write Controls the conversion rate: 0: Low Power Conversion Mode 1: Continuous Conversion Mode Note: This register must only be programmed when the device is in shutdown mode, that is, when the 'START' bit of the 'Configuration Register' (address 00h) =0 Reserved Read Only www.national.com 30 Bit Bit Name Whenever this register is programmed, all of the values in the Channel Reading Registers and Interrupt Status Registers will return to their default values. Read/Write Bit(s) Description MODE 0 0 IN0 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 1 IN1 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 2 IN2 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed 3 IN3 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 4 IN4 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 5 IN5 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 6 IN6 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 7 Temperature Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 0 IN0 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 1 IN1 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 2 IN2 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 3 IN3 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 4 IN4 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 5 IN5 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 6 IN6 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 7 IN7 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 0 IN0(+) & IN1(-) Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 1 IN3(+) & IN2(-) Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 2 IN4(+) & IN5(-) Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 3 IN7(+) & IN6(-) Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 4 Reserved Read Only 5 Reserved Read Only 6 Reserved Read Only 7 Temperature Disable Read/Write MODE 1 MODE 2 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 31 www.national.com ADC128D818 * 15.12.6 Channel Disable Register -- Address 08h Default Value [7:0] = 0000_0000 binary * This register must only be programmed when the device is in shutdown mode, that is, when the `START' bit of the "Configuration Register' (address 00h) = 0. ADC128D818 Bit Bit Name Read/Write Bit(s) Description MODE 3 0 IN0 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 1 IN1 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 2 IN2 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 3 IN3 Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 4 IN4(+) & IN5(-) Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 5 IN7(+) & IN6(-) Disable Read/Write 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 6 Reserved Read Only 7 Temperature Disable Read/Write www.national.com 1: Conversions are skipped and disabled, value register reading will be 0, and error events will be suppressed. 32 Bit Bit Name Read/Write Bit(s) Description 0 One-Shot Write Only 1: Initiate a single conversion and comparison cycle when the device is in shutdown mode or deep shutdown mode, after which the device returns to the respective mode that it was in 1-7 Reserved Read Only 15.12.8 Deep Shutdown Register -- Address 0Ah Default Value [7:0] = 0000_0000 binary Bit 0 1-7 Bit Name Read/Write Deep Shutdown Enable Read/Write Reserved Read Only Bit(s) Description 1: When 'START' = 0 (address 00h, bit 0), setting this bit high will place the device in deep shutdown mode and Interrupt Status Registers will return to their default values. 15.12.9 Advanced Configuration Register -- Address 0Bh Default Value [7:0] = 0000_0000 binary Note: Whenever the Advanced Configuration Register is programmed, all of the values in the Channel Reading Registers Bit 0 1 2 3-7 Bit Name External Reference Enable Mode Select [0] Read/Write Read/Write Read/Write Mode Select [1] Reserved Bit(s) Description 0: Selects the 2.56V internal VREF 1: Selects the variable external VREF Mode Select [1] Mode Select [0] Mode 0 0 Mode 0 0 1 Mode 1 1 0 Mode 2 1 1 Mode 3 Read Only 15.12.10 Busy Status Register -- Address 0Ch Default Value [7:0] = 0000_0010 binary Bit Bit Name Read/Write 0 Busy Read Only 1: ADC128D818 is converting Bit(s) Description 1 Not Ready Read Only 1: Waiting for the power-up sequence to end 2-7 Reserved Read Only 33 www.national.com ADC128D818 15.12.7 One-Shot Register -- Address 09h Default Value [7:0] = 0000_0000 binary ADC128D818 15.12.11 Channel Readings Registers -- Addresses 20h - 27h Address Register Name Read/Write Register Description MODE 0 20h IN0 Reading Read Only Reading for this perspective channel 21h IN1 Reading Read Only Reading for this perspective channel 22h IN2 Reading Read Only Reading for this perspective channel 23h IN3 Reading Read Only Reading for this perspective channel 24h IN4 Reading Read Only Reading for this perspective channel 25h IN5 Reading Read Only Reading for this perspective channel 26h IN6 Reading Read Only Reading for this perspective channel 27h Temperature Reading Read Only Reading for this perspective channel 20h IN0 Reading Read Only Reading for this perspective channel 21h IN1 Reading Read Only Reading for this perspective channel 22h IN2 Reading Read Only Reading for this perspective channel 23h IN3 Reading Read Only Reading for this perspective channel 24h IN4 Reading Read Only Reading for this perspective channel 25h IN5 Reading Read Only Reading for this perspective channel 26h IN6 Reading Read Only Reading for this perspective channel 27h IN7 Reading Read Only Reading for this perspective channel 20h IN0(+) & IN1(-) Reading Read Only Reading for this perspective channel 21h IN3(+) & IN2(-) Reading Read Only Reading for this perspective channel 22h IN4(+) & IN5(-) Reading Read Only Reading for this perspective channel 23h IN7(+) & IN6(-) Reading Read Only Reading for this perspective channel 24h Reserved Read Only 25h Reserved Read Only 26h Reserved Read Only 27h Temperature Reading Read Only Reading for this perspective channel 20h IN0 Reading Read Only Reading for this perspective channel 21h IN1 Reading Read Only Reading for this perspective channel 22h IN2 Reading Read Only Reading for this perspective channel 23h IN3 Reading Read Only Reading for this perspective channel 24h IN4(+) & IN5(-) Reading Read Only Reading for this perspective channel 25h IN7(+) & IN6(-) Reading Read Only Reading for this perspective channel 26h Reserved Read Only 27h Temperature Reading Read Only MODE 1 MODE 2 MODE 3 www.national.com Reading for this perspective channel 34 ADC128D818 15.12.12 Limit Registers -- Addresses 2Ah - 39h Address Register Name Read/ Register Description MODE 0 2Ah IN0 High Limit Read/Write High Limit 2Bh IN0 Low Limit Read/Write Low Limit 2Ch IN1 High Limit Read/Write High Limit 2Dh IN1 Low Limit Read/Write Low Limit 2Eh IN2 High Limit Read/Write High Limit 2Fh IN2 Low Limit Read/Write Low Limit 30h IN3 High Limit Read/Write High Limit 31h IN3 Low Limit Read/Write Low Limit 32h IN4 High Limit Read/Write High Limit 33h IN4 Low Limit Read/Write Low Limit 34h IN5 High Limit Read/Write High Limit 35h IN5 Low Limit Read/Write Low Limit 36h IN6 High Limit Read/Write High Limit 37h IN6 Low Limit Read/Write Low Limit 38h Temperature High Limit Read/Write High Limit 39h Temperature Hysteresis Limit Read/Write Hysteresis Limit 2Ah IN0 High Limit Read/Write High Limit MODE 1 2Bh IN0 Low Limit Read/Write Low Limit 2Ch IN1 High Limit Read/Write High Limit 2Dh IN1 Low Limit Read/Write Low Limit 2Eh IN2 High Limit Read/Write High Limit 2Fh IN2 Low Limit Read/Write Low Limit 30h IN3 High Limit Read/Write High Limit 31h IN3 Low Limit Read/Write Low Limit 32h IN4 High Limit Read/Write High Limit 33h IN4 Low Limit Read/Write Low Limit 34h IN5 High Limit Read/Write High Limit 35h IN5 Low Limit Read/Write Low Limit 36h IN6 High Limit Read/Write High Limit 37h IN6 Low Limit Read/Write Low Limit 38h IN7 High Limit Read/Write High Limit 39h IN7 Low Limit Read/Write Low Limit 2Ah IN0(+) & IN1(-) High Limit Read/Write High Limit MODE 2 2Bh IN0(+) & IN1(-) Low Limit Read/Write Low Limit 2Ch IN3(+) & IN2(-) High Limit Read/Write High Limit 2Dh IN3(+) & IN2(-) Low Limit Read/Write Low Limit 2Eh IN4(+) & IN5(-) High Limit Read/Write High Limit 2Fh IN4(+) & IN5(-) Low Limit Read/Write Low Limit 30h IN7(+) & IN6(-) High Limit Read/Write High Limit 31h IN7(+) & IN6(-) Low Limit Read/Write Low Limit 32h Reserved Read Only 33h Reserved Read Only 34h Reserved Read Only 35h Reserved Read Only 36h Reserved Read Only 37h Reserved Read Only 35 www.national.com ADC128D818 Address Register Name Read/ Register Description 38h Temperature High Limit Read/Write High Limit 39h Temperature Hysteresis Limit Read/Write Hysteresis Limit 2Ah IN0 High Limit Read/Write High Limit 2Bh IN0 Low Limit Read/Write Low Limit 2Ch IN1 High Limit Read/Write High Limit 2Dh IN1 Low Limit Read/Write Low Limit 2Eh IN2 High Limit Read/Write High Limit 2Fh IN2 Low Limit Read/Write Low Limit 30h IN3 High Limit Read/Write High Limit 31h IN3 Low Limit Read/Write Low Limit 32h IN4(+) & IN5(-) High Limit Read/Write High Limit 33h IN4(+) & IN5(-) Low Limit Read/Write Low Limit 34h IN7(+) & IN6(-) High Limit Read/Write High Limit 35h IN7(+) & IN6(-) Low Limit Read/Write Low Limit 36h Reserved Read Only 37h Reserved Read Only 38h Temperature High Limit Read/Write High Limit 39h Temperature Hysteresis Limit Read/Write Hysteresis Limit MODE 3 15.12.13 Manufacturer ID Register -- Address 3Eh Default Value [7:0] = 0000_0001 binary Address Register Name Read/Write 3Eh Manufacturer ID Read Only Register Description Manufacturer's ID always defaults to 0000_0001. 15.12.14 Revision ID Register -- Addresses 3Fh Default Value [7:0] = 0000_1001 binary Address 3Fh www.national.com Register Name Read/Write Revision ID Read Only Register Description Revision's ID always defaults to 0000_1001. 36 ADC128D818 16.0 Physical Dimensions inches (millimeters) unless otherwise noted 16-Lead Molded Plastic TSSOP Order Number ADC128D818CIMT or ADC128D818CIMTX NS Package Number MO-153 37 www.national.com ADC128D818 12-Bit, 8-Channel, ADC System Monitor with Temperature Sensor, Internal/ External Reference, and I2C Interface Notes For more National Semiconductor product information and proven design tools, visit the following Web sites at: www.national.com Products Design Support Amplifiers www.national.com/amplifiers WEBENCH(R) Tools www.national.com/webench Audio www.national.com/audio App Notes www.national.com/appnotes Clock and Timing www.national.com/timing Reference Designs www.national.com/refdesigns Data Converters www.national.com/adc Samples www.national.com/samples Interface www.national.com/interface Eval Boards www.national.com/evalboards LVDS www.national.com/lvds Packaging www.national.com/packaging Power Management www.national.com/power Green Compliance www.national.com/quality/green Switching Regulators www.national.com/switchers Distributors www.national.com/contacts LDOs www.national.com/ldo Quality and Reliability www.national.com/quality LED Lighting www.national.com/led Feedback/Support www.national.com/feedback Voltage References www.national.com/vref Design Made Easy www.national.com/easy www.national.com/powerwise Applications & Markets www.national.com/solutions Mil/Aero www.national.com/milaero PowerWise(R) Solutions Serial Digital Interface (SDI) www.national.com/sdi Temperature Sensors www.national.com/tempsensors SolarMagicTM www.national.com/solarmagic PLL/VCO www.national.com/wireless www.national.com/training PowerWise(R) Design University THE CONTENTS OF THIS DOCUMENT ARE PROVIDED IN CONNECTION WITH NATIONAL SEMICONDUCTOR CORPORATION ("NATIONAL") PRODUCTS. NATIONAL MAKES NO REPRESENTATIONS OR WARRANTIES WITH RESPECT TO THE ACCURACY OR COMPLETENESS OF THE CONTENTS OF THIS PUBLICATION AND RESERVES THE RIGHT TO MAKE CHANGES TO SPECIFICATIONS AND PRODUCT DESCRIPTIONS AT ANY TIME WITHOUT NOTICE. NO LICENSE, WHETHER EXPRESS, IMPLIED, ARISING BY ESTOPPEL OR OTHERWISE, TO ANY INTELLECTUAL PROPERTY RIGHTS IS GRANTED BY THIS DOCUMENT. TESTING AND OTHER QUALITY CONTROLS ARE USED TO THE EXTENT NATIONAL DEEMS NECESSARY TO SUPPORT NATIONAL'S PRODUCT WARRANTY. EXCEPT WHERE MANDATED BY GOVERNMENT REQUIREMENTS, TESTING OF ALL PARAMETERS OF EACH PRODUCT IS NOT NECESSARILY PERFORMED. NATIONAL ASSUMES NO LIABILITY FOR APPLICATIONS ASSISTANCE OR BUYER PRODUCT DESIGN. BUYERS ARE RESPONSIBLE FOR THEIR PRODUCTS AND APPLICATIONS USING NATIONAL COMPONENTS. PRIOR TO USING OR DISTRIBUTING ANY PRODUCTS THAT INCLUDE NATIONAL COMPONENTS, BUYERS SHOULD PROVIDE ADEQUATE DESIGN, TESTING AND OPERATING SAFEGUARDS. EXCEPT AS PROVIDED IN NATIONAL'S TERMS AND CONDITIONS OF SALE FOR SUCH PRODUCTS, NATIONAL ASSUMES NO LIABILITY WHATSOEVER, AND NATIONAL DISCLAIMS ANY EXPRESS OR IMPLIED WARRANTY RELATING TO THE SALE AND/OR USE OF NATIONAL PRODUCTS INCLUDING LIABILITY OR WARRANTIES RELATING TO FITNESS FOR A PARTICULAR PURPOSE, MERCHANTABILITY, OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL PROPERTY RIGHT. LIFE SUPPORT POLICY NATIONAL'S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS PRIOR WRITTEN APPROVAL OF THE CHIEF EXECUTIVE OFFICER AND GENERAL COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein: Life support devices or systems are devices which (a) are intended for surgical implant into the body, or (b) support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to result in a significant injury to the user. A critical component is any component in a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness. National Semiconductor and the National Semiconductor logo are registered trademarks of National Semiconductor Corporation. All other brand or product names may be trademarks or registered trademarks of their respective holders. Copyright(c) 2011 National Semiconductor Corporation For the most current product information visit us at www.national.com National Semiconductor Americas Technical Support Center Email: support@nsc.com Tel: 1-800-272-9959 www.national.com National Semiconductor Europe Technical Support Center Email: europe.support@nsc.com National Semiconductor Asia Pacific Technical Support Center Email: ap.support@nsc.com National Semiconductor Japan Technical Support Center Email: jpn.feedback@nsc.com IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services at any time and to discontinue any product or service without notice. Customers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. All products are sold subject to TI's terms and conditions of sale supplied at the time of order acknowledgment. TI warrants performance of its hardware products to the specifications applicable at the time of sale in accordance with TI's standard warranty. Testing and other quality control techniques are used to the extent TI deems necessary to support this warranty. Except where mandated by government requirements, testing of all parameters of each product is not necessarily performed. TI assumes no liability for applications assistance or customer product design. Customers are responsible for their products and applications using TI components. To minimize the risks associated with customer products and applications, customers should provide adequate design and operating safeguards. TI does not warrant or represent that any license, either express or implied, is granted under any TI patent right, copyright, mask work right, or other TI intellectual property right relating to any combination, machine, or process in which TI products or services are used. Information published by TI regarding third-party products or services does not constitute a license from TI to use such products or services or a warranty or endorsement thereof. Use of such information may require a license from a third party under the patents or other intellectual property of the third party, or a license from TI under the patents or other intellectual property of TI. Reproduction of TI information in TI data books or data sheets is permissible only if reproduction is without alteration and is accompanied by all associated warranties, conditions, limitations, and notices. Reproduction of this information with alteration is an unfair and deceptive business practice. TI is not responsible or liable for such altered documentation. Information of third parties may be subject to additional restrictions. Resale of TI products or services with statements different from or beyond the parameters stated by TI for that product or service voids all express and any implied warranties for the associated TI product or service and is an unfair and deceptive business practice. TI is not responsible or liable for any such statements. TI products are not authorized for use in safety-critical applications (such as life support) where a failure of the TI product would reasonably be expected to cause severe personal injury or death, unless officers of the parties have executed an agreement specifically governing such use. Buyers represent that they have all necessary expertise in the safety and regulatory ramifications of their applications, and acknowledge and agree that they are solely responsible for all legal, regulatory and safety-related requirements concerning their products and any use of TI products in such safety-critical applications, notwithstanding any applications-related information or support that may be provided by TI. Further, Buyers must fully indemnify TI and its representatives against any damages arising out of the use of TI products in such safety-critical applications. TI products are neither designed nor intended for use in military/aerospace applications or environments unless the TI products are specifically designated by TI as military-grade or "enhanced plastic." Only products designated by TI as military-grade meet military specifications. Buyers acknowledge and agree that any such use of TI products which TI has not designated as military-grade is solely at the Buyer's risk, and that they are solely responsible for compliance with all legal and regulatory requirements in connection with such use. TI products are neither designed nor intended for use in automotive applications or environments unless the specific TI products are designated by TI as compliant with ISO/TS 16949 requirements. Buyers acknowledge and agree that, if they use any non-designated products in automotive applications, TI will not be responsible for any failure to meet such requirements. Following are URLs where you can obtain information on other Texas Instruments products and application solutions: Products Applications Audio www.ti.com/audio Communications and Telecom www.ti.com/communications Amplifiers amplifier.ti.com Computers and Peripherals www.ti.com/computers Data Converters dataconverter.ti.com Consumer Electronics www.ti.com/consumer-apps DLP(R) Products www.dlp.com Energy and Lighting www.ti.com/energy DSP dsp.ti.com Industrial www.ti.com/industrial Clocks and Timers www.ti.com/clocks Medical www.ti.com/medical Interface interface.ti.com Security www.ti.com/security Logic logic.ti.com Space, Avionics and Defense www.ti.com/space-avionics-defense Power Mgmt power.ti.com Transportation and Automotive www.ti.com/automotive Microcontrollers microcontroller.ti.com Video and Imaging RFID www.ti-rfid.com OMAP Mobile Processors www.ti.com/omap Wireless Connectivity www.ti.com/wirelessconnectivity TI E2E Community Home Page www.ti.com/video e2e.ti.com Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265 Copyright (c) 2011, Texas Instruments Incorporated