ADT7318ARQ

±0.5°C Accurate Digital Temperature Sensor and Quad Voltage Output 12-/10-/8-Bit DACs ADT7316/ADT7317/ADT7318 PIN CONFIGURATION ADT7316—four 12-bit DACs ADT7317—four 10-bit DACs ADT7318—four 8-bit DACs Buffered voltage output Guaranteed monotonic by design over all codes 10-bit temperature-to-digital converter Temperature range: −40°C to +120°C Temperature sensor accuracy of ±0.5°C Supply range: 2.7 V to 5.5 V DAC output range: 0 V to 2 VREF Power-down current : 10 MΩ −90 −75 dB dB 2.2662 2.2938 V ppm/°C VDD to 0.001 V 0.5 25 16 2.5 5 Power-Up Time LDAC Pulse Width 2.28 80 0.001 DC Output Impedance Short-Circuit Current DIGITAL INPUTS5 Input Current Input Low Voltage, VIL Input High Voltage, VIH Pin Capacitance SCL, SDA Glitch Rejection VDD VDD Ω mA mA μs μs ±1 0.8 1.89 3 20 10 50 μA V V pF ns ns Rev. B | Page 4 of 44 This is a measure of the minimum and maximum drive capability of the output amplifier. VDD = 5 V. VDD = 3 V. Coming out of power-down mode. VDD = 5 V. Coming out of power-down mode. VDD = 3.3 V. VIN = 0 V to VDD. All digital inputs. Input filtering suppresses noise spikes of less than 50 ns. Edge triggered input. ADT7316/ADT7317/ADT7318 Parameter1 DIGITAL OUTPUT Output High Voltage, VOH Output Low Voltage, VOL Output High Current, IOH Output Capacitance, COUT INT/INT Output Saturation Voltage I2C TIMING CHARACTERISTICS7, 8 Serial Clock Period, t1 Data In Setup Time to SCL High, t2 Data Out Stable After SCL Low, t3 SDA Low Setup Time to SCL Low (Start Condition), t4 SDA High Hold Time After SCL High (Stop Condition), t5 SDA and SCL Fall Time, t6 SDA and SCL Rise Time, t6 SPI TIMING CHARACTERISTICS10, 11 CS to SCLK Setup Time, t1 SCLK High Pulse Width, t2 SCLK Low Pulse Width, t3 Data Access Time After SCLK Falling Edge, t412 Data Setup Time Prior to SCLK Rising Edge, t5 Data Hold Time after SCLK Rising Edge, t6 CS to SCLK Hold Time, t7 CS to DOUT High Impedance, t8 POWER REQUIREMENTS VDD VDD Settling Time IDD (Normal Mode)13 Min Typ Power Dissipation Unit Conditions/Comments 0.4 1 50 0.8 V V mA pF V ISOURCE = ISINK = 200 μA. IOL = 3 mA. VOH = 5 V. 2.4 IOUT = 4 mA. 2.5 50 0 50 μs ns ns ns Fast-mode I2C. See Figure 4. 50 ns See Figure 4. 300 3009 ns ns See Figure 4. See Figure 4. 35 ns ns ns ns See Figure 7. See Figure 7. See Figure 7. See Figure 7. 20 ns See Figure 7. 0 ns See Figure 7. 40 ns ns See Figure 7. See Figure 7. 5.5 50 3 3 10 10 10 33 V ms mA mA μA μA mW μW VDD settles to within 10% of its final voltage level. VDD = 3.3 V, VIH = VDD, and VIL = GND. VDD = 5 V, VIH = VDD , and VIL = GND. VDD = 3.3 V, VIH = VDD, and VIL = GND. VDD = 5 V, VIH = VDD, and VIL = GND. VDD = 3.3 V, using normal mode. VDD = 3.3 V, using shutdown mode. 0 50 50 0 2.7 2.2 IDD (Power-Down Mode) Max 1 See Figure 4. See Figure 4. See the Terminology section. DC specifications tested with the outputs unloaded. 3 Linearity is tested using a reduced code range: ADT7316 (Code 115 to 4095); ADT7317 (Code 28 to 1023); ADT7318 (Code 8 to 255). 4 A round robin is the continuous sequential measurement of the following three channels: VDD, internal temperature, and external temperature. 5 Guaranteed by design and characterization, but not production tested. 6 For the amplifier output to reach its minimum voltage, the offset error must be negative. For the amplifier output to reach its maximum voltage, VREF = VDD, offset plus gain error must be positive. 7 The SDA and SCL timing is measured with the input filters turned on to meet the fast-mode I2C specification. Switching off the input filters improves the transfer rate, but has a negative effect on the EMC behavior of the part. 8 Guaranteed by design. Not tested in production. 9 The interface is also capable of handling the I2C standard mode rise time specification of 1000 ns. 10 Guaranteed by design and characterization, but not production tested. 11 All input signals are specified with tr = tf = 5 ns (10% to 90% of VDD) and timed from a voltage level of 1.6 V. 12 Measured with the load circuit of Figure 5. 13 IDD specification is valid for all DAC codes. Interface inactive. All DACs active. Load currents excluded. 2 Rev. B | Page 5 of 44 ADT7316/ADT7317/ADT7318 GAIN ERROR + OFFSET ERROR OUTPUT VOLTAGE NEGATIVE OFFSET ERROR DAC CODE ACTUAL IDEAL LOWER DEAD BAND CODES AMPLIFIER FOOTROOM 02661-007 NEGATIVE OFFSET ERROR Figure 2. DAC Transfer Function with Negative Offset GAIN ERROR + OFFSET ERROR UPPER DEAD BAND CODES OUTPUT VOLTAGE POSITIVE OFFSET ERROR DAC CODE 02661-008 ACTUAL IDEAL FULL SCALE Figure 3. DAC Transfer Function with Positive Offset (VREF = VDD) t1 SCL t4 t5 t2 SDA DATA IN t6 Figure 4. I2C Bus Timing Diagram Rev. B | Page 6 of 44 02661-002 t3 SDA DATA OUT ADT7316/ADT7317/ADT7318 200µA 1.6V CL 50pF 200µA 02661-004 TO OUTPUT PIN IOL IOH Figure 5. Load Circuit for Access Time and Bus Relinquish Time VDD 4.7kΩ 4.7kΩ 200pF 02661-005 TO DAC OUTPUT Figure 6. Load Circuit for DAC Outputs CS t1 t2 t7 SCLK DIN D7 D6 D5 t6 t5 D4 D3 D2 D1 t8 D0 X X X X X X X X D5 D4 D3 D2 D1 D0 t4 DOUT X X X X X X X X D7 D6 Figure 7. SPI Bus Timing Diagram Rev. B | Page 7 of 44 02661-003 t3 ADT7316/ADT7317/ADT7318 FUNCTIONAL BLOCK DIAGRAM D– 8 ANALOG MUX A-TO-D CONVERTER VDD SENSOR VDD VALUE REGISTER LIMIT COMPARATOR TLOW LIMIT REGISTERS VDD LIMIT REGISTERS CONTROL CONFIG. 1 REGISTER EXTERNAL TEMPERATURE VALUE REGISTER DAC A REGISTERS STRING DAC A 2 VOUT-A DAC B REGISTERS STRING DAC B 1 VOUT-B DAC C REGISTERS STRING DAC C 16 VOUT-C DAC D REGISTERS STRING DAC D 15 VOUT-D CONTROL CONFIG. 2 REGISTER CONTROL CONFIG. 3 REGISTER ADT7316/ ADT7317/ ADT7318 DAC CONFIGURATION REGISTER GAIN SELECT LOGIC LDAC CONFIGURATION REGISTER STATUS REGISTERS INTERRUPT MASK REGISTERS 10 INT/INT SMBus/SPI INTERFACE 6 5 VDD GND 4 13 CS SCL/SCLK POWERDOWN LOGIC 12 11 SDA/DIN DOUT/ADD Figure 8. Rev. B | Page 8 of 44 INTERNAL REFERENCE 9 3 14 LDAC VREF-AB VREF-CD 02661-001 7 THIGH LIMIT REGISTERS DIGITAL MUX D+ ADDRESS POINTER REGISTER INTERNAL TEMPERATURE VALUE REGISTER DIGITAL MUX ON-CHIP TEMPERATURE SENSOR ADT7316/ADT7317/ADT7318 DAC AC CHARACTERISTICS Guaranteed by design and characterization, but not production tested. VDD = 2.7 V to 5.5 V; RL = 4.7 kΩ to GND; CL = 200 pF to GND; 4.7 kΩ to VDD. All specifications TMIN to TMAX, unless otherwise noted. Table 2. Parameter 1 Output Voltage Settling Time ADT7318 ADT7317 ADT7316 Slew Rate Major-Code Change Glitch Energy Digital Feedthrough Digital Crosstalk Analog Crosstalk DAC-to-DAC Crosstalk Multiplying Bandwidth Total Harmonic Distortion 1 Min Typ (@ 25°C) Max Unit 6 7 8 0.7 12 0.5 1 0.5 3 200 −70 8 9 10 μs μs μs V/μs nV-s nV-s nV-s nV-s kHz dB See Terminology section. Rev. B | Page 9 of 44 Conditions and Comments VREF = VDD = +5 V. 1/4 scale to 3/4 scale change (0x40 to 0xC0). 1/4 scale to 3/4 scale change (0x100 to 0x300). 1/4 scale to 3/4 scale change (0x400 to 0xC00). 1 LSB change around major carry. VREF = 2 V ± 0.1 V p-p. VREF = 2.5 V ± 0.1 V p-p. Frequency = 10 kHz. ADT7316/ADT7317/ADT7318 ABSOLUTE MAXIMUM RATINGS Table 3. Parameter VDD to GND Digital Input Voltage to GND Digital Output Voltage to GND Reference Input Voltage to GND Operating Temperature Range Storage Temperature Range Junction Temperature 16-Lead QSOP Power Dissipation 1 Thermal Impedance 2 θJA Junction-to-Ambient θJC Junction-to-Case IR Reflow Soldering Peak Temperature Time at Peak Temperature Ramp-Up Rate Ramp-Down Rate IR Reflow Soldering (Pb-Free Package) Peak Temperature Time at Peak Temperature Ramp-Up Rate Ramp-Down Rate Time 25°C to Peak Temperature 1 2 Rating −0.3 V to +7 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 0.3 V −40°C to +120°C −65°C to +150°C Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Table 4. I2C Address Selection 150°C (TJ max − TA)/θJA ADD Pin Low Float High 105.44°C/W 38.8°C/W 220°C (0/5°C) 10 sec to 20 sec 2°C/sec to 3°C/sec −6°C/sec ESD CAUTION 260°C (+ 0°C) 20 sec to 40 sec 3°C/sec maximum –6°C/sec maximum 8 minutes maximum Values relate to package being used on a 4-layer board. Junction-to-case resistance is applicable to components featuring a preferential flow direction, for example, components mounted on a heat sink. Junction-to-ambient resistance is more useful for air-cooled, PCBmounted components. Rev. B | Page 10 of 44 I2C Address 1001 000 1001 010 1001 011 ADT7316/ADT7317/ADT7318 VOUT-B 1 16 VOUT-C VOUT-A 2 15 VOUT-D VREF -AB 3 CS 4 GND 5 VDD 6 D+ D– ADT7316/ ADT7317/ ADT7318 14 VREF -CD 13 SCL/SCLK TOP VIEW (Not to Scale) 12 SDA/DIN 11 DOUT/ADD 7 10 INT/INT 8 9 LDAC 02661-006 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS Figure 9. Pin Configuration QSOP Table 5. Pin Function Descriptions Pin No. 1 2 3 Mnemonic VOUT-B VOUT-A VREF-AB 4 CS 5 6 7 8 9 GND VDD D+ D− LDAC 10 INT/INT 11 DOUT/ADD 12 SDA/DIN 13 SCL/SCLK 14 VREF-CD 15 16 VOUT-D VOUT-C Description Buffered Analog Output Voltage from DAC B. The output amplifier has rail-to-rail operation. Buffered Analog Output Voltage from DAC A. The output amplifier has rail-to-rail operation. Reference Input Pin for DAC A and DAC B. It may be configured as a buffered or unbuffered input to both DAC A and DAC B. It has an input range from 0.25 V to VDD in unbuffered mode and from 1 V to VDD in buffered mode. DAC A and DAC B default on power-up to this pin. SPI Active Low Control Input. This is the frame synchronization signal for the input data. When CS goes low, it enables the input register, and data is transferred in on the rising edges and out on the falling edges of the subsequent serial clocks. It is recommended that this pin be tied high to VDD when operating the serial interface in I2C mode. Ground Reference Point for All Circuitry on the Part. Analog and digital ground. Positive Supply Voltage, 2.7 V to 5.5 V. The supply should be decoupled to ground. Positive connection to external temperature sensor. Negative connection to external temperature sensor. Active low control input that transfers the contents of the input registers to their respective DAC registers. A falling edge on this pin forces any or all DAC registers to be updated if the input registers have new data. A minimum pulse width of 20 ns must be applied to the LDAC pin to ensure proper loading of a DAC register. This allows simultaneous update of all DAC outputs. Bit C3 of the Control Configuration 3 register enables the LDAC pin. Default is with the LDAC pin controlling the loading of DAC registers. Over-Limit Interrupt. The output polarity of this pin can be set to give an active low or active high interrupt when temperature or VDD limits are exceeded. Default is active low. Open-drain output—needs a pull-up resistor. DOUT: SPI Serial Data Output. Logic output. Data is clocked out of any register at this pin. Data is clocked out on the falling edge of SCLK. Open-drain output—needs a pull-up resistor. ADD: I2C Serial Bus Address Selection Pin. Logic input. A low on this pin gives the address 1001 000, leaving it floating gives the address 1001 010, and setting it high gives the address 1001 011. The I2C address set up by the ADD pin is not latched by the device until after this address has been sent twice. On the eighth SCL cycle of the second valid communication, the serial bus address is latched in. Any subsequent changes on this pin have no affect on the I2C serial bus address. SDA: I2C Serial Data Input. I2C serial data that is loaded into the device registers is provided on this input. Opendrain configuration—needs a pull-up resistor. DIN: SPI Serial Data Input. Serial data to be loaded into the device registers is provided on this input. Data is clocked into a register on the rising edge of SCLK. Open-drain configuration—needs a pull-up resistor. Serial Clock Input. This is the clock input for the serial port. The serial clock is used to clock data out of any register of the ADT7316/ADT7317/ADT7318 and also to clock data into any register that can be written to. Open-drain configuration; needs a pull-up resistor. Reference Input Pin for DAC C and DAC D. It can be configured as a buffered or unbuffered input to both DAC C and DAC D. It has an input range from 0.25 V to VDD in unbuffered mode and from 1 V to VDD in buffered mode. DAC C and DAC D default, on power-up, to this pin. Buffered Analog Output Voltage from DAC D. The output amplifier has rail-to-rail operation. Buffered Analog Output Voltage from DAC C. The output amplifier has rail-to-rail operation. Rev. B | Page 11 of 44 ADT7316/ADT7317/ADT7318 TERMINOLOGY Relative Accuracy Relative accuracy or integral nonlinearity (INL) is a measure of the maximum deviation, in LSBs, from a straight line passing through the endpoints of the DAC transfer function. Typical INL vs. code plots can be seen in Figure 10, Figure 11, and Figure 12. Differential Nonlinearity (DNL) Differential nonlinearity is the difference between the measured change and the ideal 1 LSB change between any two adjacent codes. A specified differential nonlinearity of ±0.9 LSB maximum ensures monotonicity. Typical DAC DNL vs. code plots can be seen in Figure 13, Figure 14, and Figure 15. Offset Error This is a measure of the offset error of the DAC and the output amplifier (see Figure 2 and Figure 3). It can be negative or positive. It is expressed as a percentage of the full-scale range. Gain Error This is a measure of the span error of the DAC. It is the deviation in slope of the actual DAC transfer characteristic from the ideal. It is expressed as a percentage of the full-scale range. Offset Error Drift This is a measure of the change in offset error with changes in temperature. It is expressed in ppm of full-scale range/°C. Gain Error Drift This is a measure of the change in gain error with changes in temperature. It is expressed in ppm of full-scale range/°C. Long Term Temperature Drift This is a measure of the change in temperature error with the passage of time. It is expressed in degrees Celsius. The concept of long term stability has been used for many years to describe by what amount an IC’s parameter would shift during its lifetime. This is a concept that has been typically applied to both voltage references and monolithic temperature sensors. Unfortunately, integrated circuits cannot be evaluated at room temperature (25°C) for 10 years or so to determine this shift. As a result, manufacturers very typically perform accelerated lifetime testing of integrated circuits by operating ICs at elevated temperatures (between 125°C and 150°C) over a shorter period of time (typically between 500 and 1000 hours). As a result of this operation, the lifetime of an integrated circuit is significantly accelerated due to the increase in rates of reaction within the semiconductor material. DC Power Supply Rejection Ratio (PSRR) This indicates how the output of the DAC is affected by changes in the supply voltage. PSRR is the ratio of the change in VOUT to a change in VDD for full-scale output of the DAC. It is measured in decibels. VREF is held at 2 V and VDD is varied ±10%. DC Crosstalk This is the dc change in the output level of one DAC in response to a change in the output of another DAC. It is measured with a full-scale output change on one DAC while monitoring another DAC. It is expressed in microvolts. Reference Feedthrough This is the ratio of the amplitude of the signal at the DAC output to the reference input when the DAC output is not being updated (that is, LDAC is high). It is expressed in decibels. Channel-to-Channel Isolation This is the ratio of the amplitude of the signal at the output of one DAC to a sine wave on the reference input of another DAC. It is measured in decibels. Major-Code Transition Glitch Energy Major-code transition glitch energy is the energy of the impulse injected into the analog output when the code in the DAC register changes state. It is normally specified as the area of the glitch in nV-s and is measured when the digital code is changed by 1 LSB at the major carry transition (011…11 to 100…00 or 100...00 to 011…11). Digital Feedthrough Digital feedthrough is a measure of the impulse injected into the analog output of a DAC from the digital input pins of the device but is measured when the DAC is not being written to. It is specified in nV-s and is measured with a full-scale change on the digital input pins, that is, from all 0s to all 1s or vice versa. Digital Crosstalk This is the glitch impulse transferred to the output of one DAC at midscale in response to a full-scale code change (all 0s to all 1s and vice versa) in the input register of another DAC. It is measured in standalone mode and is expressed in nV-s. Analog Crosstalk This is the glitch impulse transferred to the output of one DAC due to a change in the output of another DAC. It is measured by loading one of the input registers with a full-scale code change (all 0s to all 1s and vice versa) while keeping LDAC high. Pulse LDAC low and monitor the output of the DAC whose digital code was not changed. The area of the glitch is expressed in nV-s. DAC-to-DAC Crosstalk This is the glitch impulse transferred to the output of one DAC due to a digital code change and subsequent output change of another DAC. This includes both digital and analog crosstalk. It is measured by loading one of the DACs with a full-scale code change (all 0s to all 1s and vice versa) with LDAC low and monitoring the output of another DAC. The energy of the glitch is expressed in nV-s. Rev. B | Page 12 of 44 ADT7316/ADT7317/ADT7318 Multiplying Bandwidth The amplifiers within the DAC have a finite bandwidth. The multiplying bandwidth is a measure of this. A sine wave on the reference (with full-scale code loaded to the DAC) appears on the output. The multiplying bandwidth is the frequency at which the output amplitude falls to 3 dB below the input. Total Harmonic Distortion This is the difference between an ideal sine wave and its attenuated version using the DAC. The sine wave is used as the reference for the DAC, and the THD is a measure of the harmonics present on the DAC output. It is measured in decibels. Round Robin This term is used to describe the ADT7316/ADT7317/ ADT7318 cycling through the available measurement channels in sequence, taking a measurement on each channel. DAC Output Settling Time This is the time required, following a prescribed data change, for the output of a DAC to reach and remain within ±0.5 LSB of the final value. A typical prescribed change is from 1/4 scale to 3/4 scale. Rev. B | Page 13 of 44 ADT7316/ADT7317/ADT7318 TYPICAL PERFORMANCE CHARACTERISTICS 0.20 0.10 0.08 0.15 0.06 0.10 DNL ERROR (LSB) 0 –0.05 –0.10 0 –0.02 –0.04 –0.06 –0.15 50 100 150 DAC CODE 200 250 –0.10 0 0.6 0.3 0.4 0.2 0.2 0.1 0 –0.2 200 400 600 DAC CODE 800 1000 1000 4000 –0.1 –0.3 02661-010 0 0 1.0 2.0 0.8 1.5 0.6 1.0 0.4 DNL ERROR (LSB) 2.5 0.5 0 –0.5 –0.2 –1.5 –0.6 –2.0 –0.8 1000 1500 2000 2500 DAC CODE 3000 800 0 –0.4 500 400 600 DAC CODE 0.2 –1.0 0 200 Figure 14. ADT7317 Typical DNL Plot 3500 4000 02661-011 INL ERROR (LSB) 250 0 Figure 11. ADT7317 Typical INL Plot –2.5 200 –0.2 –0.4 –0.6 100 150 DAC CODE Figure 13. ADT7318 Typical DNL Plot DNL ERROR (LSB) INL ERROR (LSB) Figure 10. ADT7318 Typical INL Plot 50 02661-012 0 02661-013 –0.08 02661-009 –0.20 0.02 02661-014 INL ERROR (LSB) 0.04 0.05 –1.0 0 500 1000 1500 2000 2500 DAC CODE 3000 Figure 15. ADT7316 Typical DNL Plot Figure 12. ADT7316 Typical INL Plot Rev. B | Page 14 of 44 3500 ADT7316/ADT7317/ADT7318 0.30 10 0.25 INL WCP OFFSET ERROR 5 0.20 0 ERROR (LSB) 0.10 0.05 DNL WCP 0 VREF = 2.25V –5 –10 DNL WCN GAIN ERROR –15 –0.05 INL WCN 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 VREF (V) –20 02661-015 –0.10 1.0 2.7 Figure 16. ADT7318 INL Error and DNL Error vs. VREF 3.3 3.6 4.0 VDD (V) 4.5 5.0 02661-018 ERROR (LSB) 0.15 5.5 Figure 19. Offset Error and Gain Error vs. VDD 2.505 0.14 INL WCP 0.12 2.500 SOURCE CURRENT 0.10 2.495 INL WCN DAC OUTPUT (V) ERROR (LSB) 0.08 0.06 0.04 DNL WCP 0.02 2.490 2.485 SINK CURRENT 2.480 0 2.475 DNL WCN –0.04 –10 20 50 TEMPERATURE (°C) 80 110 2.465 02661-016 –0.06 –40 VDD = 5V VREF = 5V DAC OUTPUT LOADED TO MIDSCALE 2.470 0 Figure 17. ADT7318 INL Error and DNL Error vs. Temperature 1 2 4 5 6 Figure 20. VOUT Source and Sink Current Capability 1.98 0 DAC OUTPUT UNLOADED –0.2 1.96 OFFSET ERROR –0.4 1.94 ICC (mA) –0.6 –0.8 –1.0 1.92 DAC OUTPUT LOADED 1.90 –1.2 –1.4 1.88 GAIN ERROR –1.8 –40 –20 0 20 40 60 TEMPERATURE (°C) 80 100 120 1.86 0 500 1000 1500 2000 2500 DAC CODE 3000 Figure 21. Supply Current vs. DAC Code Figure 18. Offset Error and Gain Error vs. Temperature Rev. B | Page 15 of 44 3500 4000 02661-020 –1.6 02661-017 ERROR (LSB) 3 CURRENT (mA) 02661-019 –0.02 ADT7316/ADT7317/ADT7318 2.00 1.8 ADC OFF, DAC OUTPUTS AT 0V 1.6 1.4 DAC OUTPUT (V) ICC (mA) 1.95 1.90 1.85 1.2 1.0 0.8 0.6 0.4 1.80 3.1 3.5 3.9 4.3 VCC (V) 4.7 5.1 5.5 0 02661-021 1.75 2.7 0 2 4 6 8 10 TIME (µs) 02661-024 0.2 Figure 25. Exiting Power-Down to Midscale Figure 22. Supply Current vs. Supply Voltage @25°C 7 0.4700 0.4695 6 0.4690 0.4685 DAC OUTPUT (V) ICC (µA) 5 4 3 0.4680 0.4675 0.4670 0.4665 2 0.4660 1 3.9 4.3 VCC (V) 4.7 5.1 5.5 0.4650 4 6 8 10 10 Figure 26. ADT7316 Major-Code Transition Glitch Energy (0….11 to 100…00) 0.4730 3.5 0.4725 3.0 0.4720 DAC OUTPUT (V) 4.0 2.5 2.0 1.5 1.0 0.4715 0.4710 0.4705 0.4700 0.4695 0.5 0.4690 0 2 4 6 8 10 TIME (µs) 0.4685 02661-023 DAC OUTPUT (V) 2 TIME (µs) Figure 23. Power-Down Current vs. Supply Voltage @ 25°C 0 0 02661-025 3.5 02661-022 3.1 02661-026 0.4655 0 2.7 Figure 24. Half-Scale Settling (1/4 to 3/4 Scale Code Change) 0 2 4 6 TIME (µs) 8 Figure 27. ADT7316 Major-Code Transition Glitch Energy (100…00 to 011…11) Rev. B | Page 16 of 44 ADT7316/ADT7317/ADT7318 0 1.5 VDD = 5V TA = 25°C EXTERNAL TEMPERATURE @ 5V TEMPERATURE ERROR (°C) FULL-SCALE ERROR (mV) –2 –4 –6 –8 1.0 INTERNAL TEMPERATURE @ 3.3V 0.5 0 –0.5 –10 EXTERNAL TEMPERATURE @ 3.3V 1 2 3 4 –1.0 02661-027 –12 5 VREF (V) VDD = 3.3V TEMPERATURE = 25°C TEMPERATURE ERROR (°C) 10 2.327 2.326 2.325 2.324 2.323 D+ TO GND 5 0 –5 D+ TO VCC –10 –15 1 2 3 TIME (µs) 4 5 –25 02661-028 0 Figure 29. DAC-to-DAC Crosstalk 0 10 20 30 40 50 60 70 80 PCB TRACK RESISTANCE (MΩ) 90 100 02661-031 –20 Figure 32. External Temperature Error vs. PCB Track Resistance 0 0 ±100mV RIPPLE ON VCC VREF = 2.25V VDD = 3.3V TEMPERATURE = 25°C VDD = 3.3V –10 TEMPERATURE ERROR (°C) –10 –20 –30 –40 –50 –20 –30 –40 –50 10 FREQUENCY (kHz) Figure 30. PSRR vs. Supply Ripple Frequency 100 –60 02661-029 1 0 5 10 15 20 25 30 35 CAPACITANCE (nF) 40 45 50 02661-032 DAC OUTPUT (V) 120 15 VDD = 5V VREF = 5V DAC OUTPUT LOADED TO MIDSCALE 2.328 AC PSRR (dB) 85 40 Figure 31. Temperature Error @ 3.3 V and 5 V 2.329 –60 0 TEMPERATURE (°C) Figure 28. Full-Scale Error vs. VREF 2.322 –30 02661-030 INTERNAL TEMPERATURE @ 5V Figure 33. External Temperature Error vs. Capacitance Between D+ and D− Rev. B | Page 17 of 44 ADT7316/ADT7317/ADT7318 10 140 VDD = 3.3V COMMON-MODE VOLTAGE = 100mV EXTERNAL TEMPERATURE 120 4 2 0 –2 100 200 300 400 NOISE FREQUENCY (Hz) 500 600 60 40 0 02661-033 1 TEMPERATURE OF ENVIRONMENT CHANGED HERE 0 10 20 30 TIME (s) 40 50 60 Figure 37. Temperature Sensor Response to Thermal Shock Figure 34. External Temperature Error vs. Common-Mode Noise Frequency 0 70 VDD = 3.3V DIFFERENTIAL-MODE VOLTAGE = 100mV 60 –5 50 ATTENUATION (dB) TEMPERATURE ERROR (°C) INTERNAL TEMPERATURE 80 20 –4 –6 100 02661-036 6 TEMPERATURE (°C) TEMPERATURE ERROR (°C) 8 40 30 20 10 –10 –15 –20 1 100 200 300 400 NOISE FREQUENCY (MHz) 500 600 –25 02661-034 –10 Figure 35. External Temperature Error vs. Differential-Mode Noise Frequency 0.6 0.2 0 –0.2 ±250mV 1 100 200 300 400 NOISE FREQUENCY (Hz) 500 600 02661-035 TEMPERATURE ERROR (°C) 0.4 –0.6 10 100 1k 10k FREQUENCY (Hz) 100k 1M 10M Figure 38. Multiplying Bandwidth (Small-Signal Frequency Response) VDD = 3.3V –0.4 1 02661-037 0 Figure 36. Internal Temperature Error vs. Power Supply Noise Frequency Rev. B | Page 18 of 44 ADT7316/ADT7317/ADT7318 THEORY OF OPERATION Directly after the power-up calibration routine, the ADT7316/ ADT7317/ADT7318 go into idle mode. In this mode, the device is not performing any measurements and is fully powered up. All four DAC outputs are at 0 V. To begin monitoring, write to the Control Configuration 1 register (Address 0x18), and set Bit C0 = 1. The ADT7316/ ADT7317/ADT7318 go into their power-up default measurement mode, which is round robin. The device proceeds to take measurements on the VDD channel, the internal temperature sensor channel, and the external temperature sensor channel. Once it finishes taking measurements on the external temperature sensor channel, the device immediately loops back to start taking measurements on the VDD channel and repeats the same cycle as before. This loop continues until the monitoring is stopped by resetting Bit C0 of the Control Configuration 1 register to 0. only be switched back to be I2C when the device is powered off and on. When using I2C, the CS pin should be tied to either VDD or GND. There are a number of different operating modes on the ADT7316/ADT7317/ADT7318 devices, and all of them can be controlled by the configuration registers. These features consist of enabling and disabling interrupts, polarity of the INT/INT pin, enabling and disabling the averaging on the measurement channels, SMBus timeout, and software reset. POWER-UP CALIBRATION It is recommended that no communication to the part is initiated until approximately 5 ms after VDD has settled to within 10% of its final value. It is generally accepted that most systems take a maximum of 50 ms to power-up. Power-up time is directly related to the amount of decoupling on the voltage supply line. It is also possible to continue monitoring as well as switching to single-channel mode by writing to the Control Configuration 2 register (Address 0x19) and setting Bit C4 = 1. Further explanation of the single-channel and round robin measurement modes is given in later sections. All measurement channels have averaging enabled on power-up. Averaging forces the device to take an average of 16 readings before giving a final measured result. To disable averaging and consequently decrease the conversion time by a factor of 16, set C5 = 1 in the Control Configuration 2 register. During the 5 ms after VDD has settled, the part performs a calibration routine; any communication to the device interrupts this routine and can cause erroneous temperature measurements. If it is not possible to have VDD at its nominal value by the time 50 ms has elapsed, or that communication to the device has started prior to VDD settling, then it is recommended that a measurement be taken on the VDD channel before a tempera ture measurement is taken. The VDD measurement is used to calibrate out any temperature measurement error due to different supply voltage values. Controlling the DAC outputs can be done by writing to the DAC MSB and LSB registers (Address 0x10 to Address 0x17). The power-up default setting is to have a low going pulse on the LDAC pin controlling the updating of the DAC outputs from the DAC registers. Alternatively, users can configure the updating of the DAC outputs to be controlled by means other than the LDAC pin by setting C3 = 1 of the Control Configuration 3 register (Address 0x1A). The DAC Configuration register (Address 0x1B), and the LDAC Configuration register (Address 0x1C) can then be used to control the DAC updating. These two registers also control the output range of the DACs, enabling or disabling the external reference buffer, and selecting between the internal or external reference. DAC A and DAC B outputs can be configured to give a voltage output proportional to the temperature of the internal and external temperature sensors, respectively. CONVERSION SPEED The dual serial interface defaults to the I2C protocol on powerup. To select and lock in the SPI protocol, follow the selection process as described in the Serial Interface Selection section. The I2C protocol cannot be locked in, while the SPI protocol, when selected, is automatically locked in. The interface can The internal oscillator circuit used by the ADC has the capability to output two different clock frequencies. This means that the ADC is capable of running at two different speeds when performing a conversion on a measurement channel. Thus, the time taken to perform a conversion on a channel can be reduced by setting C0 of Control Configuration 3 register (Address 0x1A). This increases the ADC clock speed from 1.4 kHz to 22 kHz. At the higher clock speed, the analog filters on the D+ and D− input pins (external temperature sensor) are switched off. This is why the power-up default setting is to have the ADC working at the slow speed. The typical times for fast and slow ADC speeds are given in the Specifications section. The ADT7316/ADT7317/ADT7318 power up with averaging on. This means every channel is measured 16 times and internally averaged to reduce noise. The conversion time can also be sped up by turning the averaging off; to do so, set Bit C5 of the Control Configuration 2 register (Address 0x19) to 1. Rev. B | Page 19 of 44 ADT7316/ADT7317/ADT7318 FUNCTIONAL DESCRIPTION—VOLTAGE OUTPUT DIGITAL-TO-ANALOG CONVERTERS DIGITAL-TO-ANALOG SECTION The ADT7316/ADT7317/ADT7318 have four resistor-string DACs fabricated on a CMOS process, with resolutions of 12, 10, and 8 bits, respectively. They contain four output buffer amplifiers and are written to via an I2C serial interface or an SPI serial interface. See the Serial Interface Selection section for more information. The architecture of a DAC channel consists of a resistor string DAC followed by an output buffer amplifier. The voltage at the VREF pin or the on-chip reference of 2.28 V provides the reference voltage for the corresponding DAC. Figure 39 shows a block diagram of the DAC architecture. Because the input coding to the DAC is straight binary, the ideal output voltage is given by The ADT7316/ADT7317/ADT7318 operate from a single supply of 2.7 V to 5.5 V, and the output buffer amplifiers provide railto-rail output swing with a slew rate of 0.7 V/μs. DAC A and DAC B share a common external reference input, namely V REF-AB. DAC C and DAC D share a common external reference input, namely VREF-CD. Each reference input may be buffered to draw virtually no current from the reference source or unbuffered to give a reference input range from GND to VDD. The devices have a power-down mode in which all DACs may be turned off completely with a high impedance output. Each DAC output is not updated until it receives the LDAC command. Therefore, while a new value is written to the DAC registers, this value is not represented by a voltage output until the DACs receive the LDAC command. Reading back from any DAC register prior to issuing an LDAC command results in the digital value that corresponds to the DAC output voltage. Therefore, the digital value written to the DAC register cannot be read back until after the LDAC command has been initiated. This LDAC command can be given by either pulling the LDAC pin low (falling edge loads DACs), setting up Bit D4 and Bit D5 of the DAC Configuration register (Address 0x1B), or using the LDAC Configuration register (Address 0x1C). VOUT = V REF × D 2N where: D = the decimal equivalent of the binary code that is loaded to the DAC register: 0 to 255 for ADT7318 (8 bits). 0 to 1023 for ADT7317 (10 bits). 0 to 4095 for ADT7316 (12 bits). N = the DAC resolution. RESISTOR STRING The resistor string section is shown in Figure 40. It is a string of resistors, each approximately 603 Ω. The digital code loaded to the DAC register determines the node on the string where the voltage is tapped off to be fed into the output amplifier. The voltage is tapped off by closing one of the switches connecting the string to the amplifier. Because it is a string of resistors, it is guaranteed monotonic. R R R When using the LDAC pin to control DAC register loading, the low going pulse width should be 20 ns minimum. The LDAC pin has to go high and low again before the DAC registers can be reloaded. TO OUTPUT AMPLIFIER R VREF -AB 02661-039 R BUFFER SELECT SIGNAL RESISTOR STRING VOUT-A OUTPUT BUFFER AMPLIFIER Figure 39. Single DAC Channel Architecture 02661-038 DAC REGISTER DAC EXTERNAL REFERENCE INPUTS GAIN MODE (GAIN = 1 OR 2) INT VREF INPUT REGISTER Figure 40. Resistor String REFERENCE BUFFER There is a reference pin for each pair of DACs. The reference inputs are buffered, but can also be individually configured as unbuffered. The advantage with the buffered input is the high impedance it presents to the voltage source driving it. However, if the unbuffered mode is used, the user can have a reference voltage as low as 0.25 V and as high as VDD, because there is no restriction due to headroom and footroom of the reference amplifier. If there is a buffered reference in the circuit, there is no need to use the on-chip buffers. In unbuffered mode, the input impedance is still large at typically 90 kΩ per reference input for 0 V to VREF output mode and 45 kΩ for 0 V to 2 VREF output mode. Rev. B | Page 20 of 44 ADT7316/ADT7317/ADT7318 VDD I N×I IBIAS OPTIONAL CAPACITOR, UP TO 3nF MAX. CAN BE ADDED TO IMPROVE HIGH FREQUENCY NOISE REJECTION IN NOISY ENVIRONMENTS D+ VOUT+ C1 TO ADC D– LOW-PASS FILTER fC = 65kHz BIAS DIODE VOUT– 02661-041 REMOTE SENSING TRANSISTOR (2N3906) Figure 41. Signal Conditioning for External Diode Temperature Sensors proportional to output voltage. Each time a temperature measurement is taken, the DAC output is updated. The output resolution for the ADT7318 is 8 bits with the 1°C change corresponding to the 1 LSB change. The output resolution for the ADT7316 and ADT7317 is capable of 10 bits with a 0.25°C change corresponding to the 1 LSB change. The buffered/unbuffered option is controlled by the DAC Configuration register (Address 0x1B; see the Registers section). The LDAC Configuration register controls the selection between internal and external voltage references. The default setting is for external reference to be selected. VREF -AB The default output resolution for the ADT7316 and ADT7317 is 8 bits. To increase this to 10 bits, set C1 = 1 of the Control Configuration 3 register (Address 0x1A). The default output range is 0 V to VREF-AB, and this can be increased to 0 V to 2 VREF-AB. The user can select the internal VREF (VREF = 2.28 V) by setting D4 = 1 in the LDAC Configuration register (Address 0x1C). Increasing the output voltage span to 2 VREF can be done by setting D0 = 1 for DAC A (internal temperature sensor), and D1 = 1 for DAC B (external temperature sensor) in the DAC Configuration register (Address 0x1B). 2.25V INTERNAL VREF STRING DAC B 02661-040 STRING DAC A Figure 42. DAC Reference Buffer Circuit OUTPUT AMPLIFIER The output buffer amplifier is capable of generating output voltages to within 1 mV of either rail. Its actual range depends on the value of VREF, gain, and offset error. If a gain of 1 is selected (Bit 0 to Bit 3 = 0, DAC Configuration register, Address 0x1B), the output range is 0.001 V to VREF. If a gain of 2 is selected (Bit 0 to Bit 3 = 1, DAC Configuration register, Address 0x1B), the output range is 0.001 V to 2 VREF. Because of clamping, however, the maximum output is limited to VDD – 0.001 V. The output amplifier is capable of driving a load of 4.7 kΩ to VDD or 4.7 kΩ to GND in parallel with 200 pF to GND (see Figure 6). The source and sink capabilities of the output amplifier can be seen in Figure 20. The slew rate is 0.7 V/μs with a half-scale settling time to ±0.5 LSB (at 8 bits) of 6 μs. The output voltage is capable of tracking a maximum temperature range of −128°C to +127°C, but the default setting is −40°C to +127°C. If the output voltage range is 0 V to VREF-AB (VREF-AB = 2.25 V), then this corresponds to 0 V representing −40°C, and 1.48 V representing +127°C. This gives an upper dead band between 1.48 V and VREF-AB. The internal and external analog temperature offset registers can be used to vary this upper dead band, and consequently, the temperature that 0 V corresponds to. Table 6 and Table 7 give examples of how this is done using a DAC output voltage span of VREF and 2 VREF, respectively. Write in the temperature value, in twos complement format, at which 0 V is to start. For example, if using the DAC A output with 0 V to start at −40°C, program 0xD8 into the internal analog temperature offset register (Address 0x21). This is an 8-bit register, and thus, only has a temperature offset resolution of 1°C for all device models. Use the following formulas to determine the value to program into the offset registers. THERMAL VOLTAGE OUTPUT The ADT7316/ADT7317/ADT7318 are capable of outputting voltages that are proportional to temperature. The DAC A output can be configured to represent the temperature of the internal sensor while DAC B output can be configured to represent the external temperature sensor. Bit C5 and Bit C6 of the Control Configuration 3 register select the temperature Rev. B | Page 21 of 44 ADT7316/ADT7317/ADT7318 Negative Temperatures Table 7. Thermal Voltage Output (0 V to 2 VREF-AB) Offset Register Code (dec) = (0 V Temp) + 128 where D7 of Offset Register Code is set to 1 for negative temperatures. Example: Offset Register Code (dec ) = ( −40 ) + 128 = 88d = 0 x58 Because a negative temperature is input into the equation, DB7 (MSB) of the Offset Register Code is set to 1. Therefore, 0x58 becomes 0xD8: 0 x 58 + DB7 (1) = 0 xD8 Positive Temperatures Offset Register Code (dec ) = 0 V Temp Example: Offset Register Code (dec ) = 10d = 0x0A The following equation is used to work out the various temperatures for the corresponding 8-bit DAC output: 8-Bit Temp = (DAC O/P ÷ 1 LSB) + (0 V Temp) For example, if the output is 1.5 V, VREF-AB = 2.25 V, 8-bit DAC has an LSB size = 2.25 V/256 = 8.79 × 10–3, and 0 V temp is at −128°C, then the resultant temperature is (1.5 ÷ 8.79 × 10 ) + (− 128) = + 43 o C −3 Output Voltage (V) 0 0.25 0.5 0.75 1 1.12 1.47 1.5 2 2.25 2.5 2.75 3 3.25 3.5 3.75 4 4.25 4.5 Default (°C) −40 −26 +12 +3 +17 +23 +43 +45 +73 +88 +102 +116 UDB1 UDB1 UDB1 UDB1 UDB1 UDB1 UDB1 Max (°C) −128 −114 −100 −85 −71 −65 −45 −43 −15 0 +14 +28 +42 +56 +70 +85 +99 +113 +127 Sample (°C) 0 +14 +28 +43 +57 +63 +83 +85 +113 +127 UDB1 UDB1 UDB1 UDB1 UDB1 UDB1 UDB1 UDB1 UDB1 1 Upper dead band has been reached. DAC output is not capable of increasing (see Figure 3). Figure 43 shows the DAC output vs. temperature for a VREF-AB = 2.25 V. 2.25 The following equation is used to work out the various temperatures for the corresponding 10-bit DAC output 2.10 10-Bit Temp = ((DAC O/P ÷ 1 LSB) × 0.25) + (0 V Temp) 1.65 1.95 For example, if the output is 0.4991 V, VREF-AB = 2.25 V, 10-bit DAC has an LSB size = 2.25 V/1024 = 2.197 × 10-3, and 0 V temp is at −40°C, then the resulting temperature is ((0.4991 ÷ 2.197 × 10 −3 ) × 0.25) + (− 40) = 16.75 o C Max (°C) −128 −71 −15 −1 +39 +42 +99 +127 1.50 1.35 0V = –40°C 1.20 1.05 0.90 0.75 0V = 0°C 0.45 Sample (°C) 0 +56 +113 +127 UDB1 UDB1 UDB1 UDB1 1 Upper dead band has been reached. DAC output is not capable of increasing (see Figure 3). Rev. B | Page 22 of 44 0.30 0.15 0 –128 –110 –90 –70 –50 –30 –10 10 30 50 TEMPERATURE (°C) 70 90 110 127 Figure 43. 10-Bit DAC Output vs. Temperature, VREF-AB = 2.25 V 02661-042 Default (°C) −40 +17 +73 +87 +127 UDB1 UDB1 UDB1 0V = –128°C 0.60 Table 6. Thermal Voltage Output (0 V to VREF-AB) Output Voltage (V) 0 0.5 1 1.12 1.47 1.5 2 2.25 DAC OUTPUT (V) 1.80 ADT7316/ADT7317/ADT7318 FUNCTIONAL DESCRIPTION—MEASUREMENT TEMPERATURE SENSOR The ADT7316/ADT7317/ADT7318 contain an ADC with special input signal conditioning to enable operation with external and on-chip diode temperature sensors. When the ADT7316/ ADT7317/ADT7318 are operating in single-channel mode, the ADC continually processes the measurement taken on one channel only. This channel is preselected by Bit C0 and Bit C1 in the Control Configuration 2 register (Address 0x19). When in round robin mode, the analog input multiplexer sequentially selects the VDD input channel, the on-chip temperature sensor to measure its internal temperature, and the external temperature sensor. These signals are digitized by the ADC and the results stored in the various value registers. The measured results are compared with the internal and external, THIGH and TLOW, limits. These temperature limits are stored in on-chip registers. If the temperature limits are not masked out, any out-of-limit comparisons generate flags that are stored in the Interrupt Status 1 register (Address 0x00). One or more out-of-limit results cause the INT/INT output to pull either high or low depending on the output polarity setting. Theoretically, the temperature measuring circuit can measure temperatures from −128°C to +127°C with a resolution of 0.25°C. Temperatures outside TA, however, are outside the guaranteed operating temperature range of the device. Temperature measurement from −128°C to +127°C is possible using an external sensor. Temperature measurement is initiated by three methods. The first method is applicable when the part is in single-channel measurement mode. The temperature is measured 16 times and internally averaged to reduce noise. In single-channel mode, the part continuously monitors the selected channel, that is, as soon as one measurement is taken, then another one is started on the same channel. The total time to measure a temperature channel with the ADC operating at slow speed is typically 11.4 ms (712 μs × 16) for the internal temperature sensor, and 24.22 ms (1.51 ms × 16) for the external temperature sensor. The new temperature value is stored in two 8-bit registers and ready for reading by the I2C or SPI interface. The user can disable the averaging by setting Bit 5 = 1 in the Control Configuration 2 register (Address 0x19). The ADT7316/ADT7317/ ADT7318 default on power-up, with the averaging enabled. The third temperature measurement method is initiated after every read or write to the part when the part is in either singlechannel measurement mode or round robin measurement mode. Once serial communication has started, any conversion in progress is stopped and the ADC reset. Conversion starts again immediately after the serial communication has finished. The temperature measurement proceeds normally as described earlier. VDD MONITORING The ADT7316/ADT7317/ADT7318 can monitor their own power supplies. The parts measure the voltage on their VDD pin to a resolution of 10 bits. The resulting value is stored in two 8-bit registers: the 2 LSBs are stored in the Internal Temperature Value/VDD Value register (Address 0x03) and the 8 MSBs are stored in the VDD Value Register MSBs register (Address 0x06). This allows the user to perform a 1-byte read if 10-bit resolution is not important. The measured result is compared with VHIGH and VLOW limits. If the VDD interrupt is not masked out, any outof-limit comparison generates a flag in the Interrupt Status 2 register (Address 0x10), and one or more out-of-limit results cause the INT/INT output to pull either high or low depending on the output polarity setting. Measuring the voltage on the VDD pin is regarded as monitoring a channel. Therefore, along with the internal and external temperature sensors, the VDD voltage makes up the third and final monitoring channel. The user can select the VDD channel for single-channel measurement by setting Bit C4 = 1 and setting Bit C0 to Bit C2 to all 0s in the Control Configuration 2 register (Address 0x19). When measuring the VDD value, the reference for the ADC is sourced from the internal reference. Table 8 shows the data format. As the maximum VDD voltage measurable is 7 V, internal scaling is performed on the VDD voltage to match the 2.28 V internal reference value. An example of how the transfer function works follows. The second temperature measurement method is applicable when the part is in round robin measurement mode. The part measures both the internal and external temperature sensors as it cycles through all possible measurement channels. The two temperature channels are measured each time the part runs a round robin sequence. In round-robin mode, the part continuously measures all channels. Rev. B | Page 23 of 44 VDD = 5 V ADC Reference = 2.28 V 1 LSB = ADC Reference/210 = 2.28/1024 = 2.226 mV Scale Factor = Full-Scale VCC/ADC Reference = 7/2.28 = 3.07 Conversion Result = VDD/(Scale Factor × LSB Size) = 5/(3.07 × 2.226 mV) = 0x2DB ADT7316/ADT7317/ADT7318 VDD Table 8. VDD Data Format, VREF = 2.28 V Digital Output Binary 01 0110 1110 01 1011 0111 10 0000 0000 10 0100 1001 10 1001 0010 10 1101 1100 11 0010 0101 11 0110 1110 11 1011 0111 11 1111 1111 Hex 16E 1B7 200 249 292 2DC 325 36E 3B7 3FF N×I IBIAS VOUT+ TO ADC INTERNAL SENSE TRANSISTOR BIAS DIODE VOUT– 02661-043 VDD Value (V) 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 I Figure 44. Top Level Structure of Internal Temperature Sensors SINGLE-CHANNEL MEASUREMENT ON-CHIP REFERENCE The ADT7316/ADT7317/ADT7318 have an on-chip 1.2 V band gap reference that is gained up by a switched capacitor amplifier to give an output of 2.28 V. The amplifier is powered up for the duration of the device monitoring phase and is powered down once monitoring is disabled. This saves on current consumption. The internal reference is used as the reference for the ADC. The ADC is used for measuring VDD and the internal and external temperature sensors. The internal reference is always used when measuring VDD, and the internal and external temperature sensors. The external reference is the default power-up reference for the DACs. ROUND ROBIN MEASUREMENT On power-up, the ADT7316/ADT7317/ADT7318 go into round robin mode, but monitoring is disabled. Setting Bit C0 of the Configuration 1 Register (Address 0x18) to 1 enables conversions. It sequences through the three channels of VDD, the internal temperature sensor, and the external temperature sensor and takes a measurement from each. Once the conversion is completed on the external temperature sensor, the device loops around for another measurement cycle on all three channels. (This method of taking a measurement on all three channels in one cycle is called round robin.) Setting Bit 4 of the Control Configuration 2 register (Address 0x19) disables the round-robin mode and in turn sets up the single-channel mode. The single-channel mode is where only one channel (for example, the internal temperature sensor) is measured in each conversion cycle. Setting C4 of the Control Configuration 2 register (Address 0x19) enables the single-channel mode and allows the ADT7316/ ADT7317/ ADT7318 to focus on one channel only. A channel is selected by writing to Bit C0 and Bit C1 in the Control Configuration 2 register. For example, to select the VDD channel for monitoring, write to the Control Configuration 2 register and set C4 = 1 (if this has not been done), then write all 0s to Bit C0 to Bit C1. All subsequent conversions are done on the VDD channel only. To change the channel selection to the internal temperature channel, write to the Control Configuration 2 register and set C0 = 1. When measuring in single-channel mode, conversions on the channel selected occur directly after each other. Any communication to the ADT7316/ADT7317/ ADT7318 stops the conversions, but they are restarted once the read or write operation is completed. TEMPERATURE MEASUREMENT METHOD Internal Temperature Measurement The ADT7316/ADT7317/ADT7318 contain an on-chip, band gap temperature sensor whose output is digitized by the on-chip ADC. The temperature data is stored in the internal temperature value register. As both positive and negative temperatures can be measured, the temperature data is stored in twos complement format, as shown in Table 9. The thermal characteristics of the measurement sensor can change, and therefore an offset is added to the measured value to enable the transfer function to match the thermal characteristics. This offset is added before the temperature data is stored. The offset value used is stored in the internal temperature offset register. The time taken to monitor all channels is typically not of interest, because the most recently measured value can be read at any time. External Temperature Measurement For applications where the round-robin time is important, typical times at 25°C are given in the Specifications section. The forward voltage of a diode or diode-connected transistor, operated at a constant current, exhibits a negative temperature coefficient of about –2 mV/°C. Unfortunately, the absolute value of VBE varies from device to device, and individual calibration is required to null this out, so the technique is unsuitable for mass production. The ADT7316/ADT7317/ADT7318 can measure the temperature of one external diode sensor or diode-connected transistor. Rev. B | Page 24 of 44 ADT7316/ADT7317/ADT7318 The technique used in the ADT7316/ADT7317/ADT7318 is to measure the change in VBE when the device is operated at two different currents. This is given by ΔVBE = KT/q × ln (N) where: K is Boltzmann’s constant. q is the charge on the carrier. T is the absolute temperature in Kelvin. N is the ratio of the two currents. Figure 41 shows the input signal conditioning used to measure the output of an external temperature sensor. This figure shows the external sensor as a discrete substrate transistor. If a PNP transistor is used, the base is connected to the D− input and the emitter to the D+ input. If an NPN transistor is used, the emitter is connected to the D− input and the base to the D+ input. A 2N3906 is recommended to be used as the external transistor. To prevent ground noise interfering with the measurement, the more negative terminal of the sensor is not referenced to ground, but is biased above ground by an internal diode at the D− input. As the sensor is operating in a noisy environment, C1 is provided as a noise filter. See the Layout Considerations section on for more information on C1. To measure ΔVBE, the sensor is switched between operating currents of I and N × I. The resulting waveform is passed through a low-pass filter to remove noise, then to a chopper stabilized amplifier that performs the functions of amplification and rectification of the waveform to produce a dc voltage proportional to ΔVBE. This voltage is measured by the ADC to give a temperature output in 10-bit twos complement format. To further reduce the effects of noise, digital filtering is performed by averaging the results of 16 measurement cycles. TEMPERATURE VALUE FORMAT One LSB of the ADC corresponds to 0.25°C. The ADC can theoretically measure a temperature span of 255°C. The internal temperature sensor is guaranteed to a low value limit of −40°C. It is possible to measure the full temperature span using the external temperature sensor. The temperature data format is shown in Table 9. The result of the internal or external temperature measurements is stored in the temperature value registers and is compared with limits programmed into the internal or external high and low registers. Table 9. Temperature Data Format (Internal and External Temperature) Temperature −40°C −25°C −10°C −0.25°C 0°C 0.25°C 10°C 25°C 50°C 75°C 100°C 105°C 125°C Digital Output DB9..........DB0 11 0110 0000 11 1001 1100 11 1101 1000 11 1111 1111 00 0000 0000 00 0000 0001 00 0010 1000 00 0110 0100 00 1100 1000 01 0010 1100 01 1001 0000 01 1010 0100 01 1111 0100 Temperature Conversion Formula Positive Temperature = ADC Code/4 Negative Temperature = (ADC Code − 512)/4 where DB9 is removed from the ADC code in the Negative Temperature equation. Rev. B | Page 25 of 44 ADT7316/ADT7317/ADT7318 INTERRUPTS The measured results from the internal temperature sensor, external temperature sensor, and the VDD pin are compared with the THIGH/VHIGH (greater than comparison) and TLOW/VLOW (less than or equal to comparison) limits. An interrupt occurs if the measurement exceeds or equals the limit registers. These limits are stored in on-chip registers. Note that the limit registers are 8 bits long, while the conversion results are 10 bits long. If the limits are not masked out, then any out-of-limit comparisons generate flags that are stored in the Interrupt Status 1 register (Address 0x00) and the Interrupt Status 2 register (Address 0x01). One or more out-of-limit results cause the INT/INT output to pull either high or low depending on the output polarity setting. It is good design practice to mask out interrupts for channels that are of no concern to the application. Figure 45 shows the interrupt structure for the ADT7316/ ADT7317/ADT7318. It shows a block diagram of how the various measurement channels affect the INT/INT pin. S/W RESET INTERNAL TEMP INTERRUPT STATUS REGISTER 1 (TEMP AND EXT. DIODE CHECK) STATUS BITS EXTERNAL TEMP INTERRUPT MASK REGISTERS WATCHDOG LIMIT COMPARISONS INTERRUPT STATUS REGISTER 2 (VDD) VDD INT/INT (LATCHED OUTPUT) STATUS BIT DIODE FAULT CONTROL CONFIGURATION REGISTER 1 INT/INT ENABLE BIT Figure 45. ADT7316/ADT7317/ADT7318 Interrupt Structure Rev. B | Page 26 of 44 02661-044 READ RESET ADT7316/ADT7317/ADT7318 REGISTERS The ADT7316/ADT7317/ADT7318 contain registers that are used to store the results of external and internal temperature measurements, VDD value measurements, high and low temperature and supply voltage limits. They also set output DAC voltage levels, configure multipurpose pins, and generally control the device. A description of these registers follows. The register map is divided into registers of 8 bits. Each register has its own individual address, but some consist of data that is linked with other registers. These registers hold the 10-bit conversion results of measurements taken on the temperature and VDD channels. For example, the 8 MSBs of the VDD measurement are stored in VDD Value Register MSBs Register (Address 0x06), while the 2 LSBs are stored in Internal Temperature Value/VDD Value LSBs Register Address 0x03. These types of registers are linked in that when the LSB register is read first, the MSB registers associated with that LSB register are locked out to prevent any updates. To unlock these MSB registers, the user has only to read any one of them, which effectively unlocks all previously locked-out MSB registers. Therefore, for the example given earlier, if Register 0x03 is read first, MSB Register 0x06 and Register 0x07 are locked out to prevent any updates to them. If Register 0x06 is read, then this register and Register 0x07 would be subsequently unlocked. LSB REGISTER OUTPUT DATA 02661-046 FIRST READ COMMAND LOCK ASSOCIATED MSB REGISTERS Figure 46. Phase 1 of 10-Bit Read MSB REGISTER OUTPUT DATA UNLOCK ASSOCIATED MSB REGISTERS 02661-047 SECOND READ COMMAND Figure 47. Phase 2 of 10-Bit Read If an MSB register is read first, its corresponding LSB register is not locked out, allowing the user to read back only 8 bits (MSB) of a 10-bit conversion result. Reading an MSB register first does not lock out other MSB registers, and likewise, reading an LSB register first does not lock out other LSB registers. Table 10. List of ADT7316/ADT7317/ADT7318 Registers RD/WR Address 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 to 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 0x16 0x17 0x18 0x19 0x1A 0x1B 0x1C 0x1D 0x1E 0x1F 0x20 0x21 0x22 0x23 0x24 0x25 0x26 0x27 0x28 0x29 to 0x4C 0x4D 0x4E 0x4F 0x50 to 0x7E 0x7F 0x80 to 0xFF Rev. B | Page 27 of 44 Name Interrupt Status 1 Interrupt Status 2 Reserved Internal Temp and VDD LSBs External Temp LSBs Reserved VDD MSBs Internal Temp MSBs External Temp MSBs Reserved DAC A LSBs (ADT7316/ADT7317 only) DAC A MSBs DAC B LSBs (ADT7316/ADT7317 only) DAC B MSBs DAC C LSBs (ADT7316/ADT7317 only) DAC C MSBs DAC D LSBs (ADT7316/ADT7317 only) DAC D MSBs Control Configuration 1 Control Configuration 2 Control Configuration 3 DAC Configuration LDAC Configuration Interrupt Mask 1 Interrupt Mask 2 Internal Temp Offset External Temp Offset Internal Analog Temp Offset External Analog Temp Offset VDD VHIGH Limit VDD VLOW Limit Internal THIGH Limit Internal TLOW Limit External THIGH Limit External TLOW Limit Reserved Device ID Manufacturer’s ID Silicon Revision Reserved SPI Lock Status Reserved Power-On Default 0x00 0x00 0x00 0x00 0x00 0x00 0xxx 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0xD8 0xD8 0xC7 0x62 0x64 0xC9 0xFF 0x00 0x01/0x09/0x05 0x41 0xXx 0x00 0x00 0x00 ADT7316/ADT7317/ADT7318 REGISTER DESCRIPTIONS Table 15. Internal Temperature/VDD LSBs The bit maps in this section show the register default settings at power-up, unless otherwise noted. D7 N/A N/A Interrupt Status 1 Register (Read-Only) [Address 0x00] This 8-bit, read-only register reflects the status of some of the interrupts that can cause the INT/INT pin to go active. This register is reset by a read operation, provided that any out-oflimit event has been corrected. It is also reset by a software reset. Table 11. Interrupt Status 1 Register D7 N/A 1 D6 N/A D5 N/A D4 01 D3 01 D2 01 D1 01 D0 01 Default settings at power-up. Table 12. Interrupt Status 1 Register Bit D0 D1 D2 D3 D4 Function 1 when internal temperature value exceeds THIGH limit. Any internal temperature reading greater than the limit set causes an out-of-limit event. 1 when internal temperature value exceeds TLOW limit. Any internal temperature reading less than or equal to the limit set causes an out-of-limit event. 1 when external temperature value exceeds THIGH limit. The default value for this limit register is –1°C, so any external temperature reading greater than the limit set causes an out-of-limit event. 1 when external temperature value exceeds TLOW limit. The default value for this limit register is 0°C, so any external temperature reading less than or equal to the limit set causes an out-of-limit event. 1 indicates a fault (open or short) for the external temperature sensor. 1 D6 N/A N/A D5 N/A N/A D4 N/A N/A D3 V1 01 D2 LSB 01 D1 T1 01 D0 LSB 01 Default settings at power-up. Table 16. Internal Temperature/VDD LSBs Bit Descriptions Bit D0 D1 D2 D3 Function LSB of internal temperature value. B1 of internal temperature value. LSB of VDD value. B1 of VDD value. External Temperature Value Register LSBs (Read-Only) [Address 0x04] This 8-bit, read-only register stores the 2 LSBs of the 10-bit temperature reading from the external temperature sensor. Table 17. External Temperature LSBs D7 N/A N/A 1 D6 N/A N/A D5 N/A N/A D4 N/A N/A D3 N/A N/A D2 N/A N/A D1 T1 01 D0 LSB 01 Default settings at power-up. Table 18. External Temperature LSBs Bit Descriptions Bit D0 D1 Function LSB of external temperature value. B1 of external temperature value. VDD Value Register MSBs (Read-Only) [Address 0x06] This 8-bit, read-only register stores the supply voltage value. The 8 MSBs of the 10-bit value are stored in this register. Interrupt Status 2 Register (Read-Only) [Address 0x01] This 8-bit, read-only register reflects the status of the VDD interrupt that can cause the INT/INT pin to go active. This register is reset by a read operation, provided that any out-oflimit event has been corrected. It is also reset by a software reset. Table 19. VDD Value MSBs Table 13. Interrupt Status 2 Register Internal Temperature Value Register MSBs (Read-Only) [Address 0x07] This 8-bit, read-only register stores the internal temperature value from the internal temperature sensor in twos complement format. The 8 MSBs of the 10-bit value are stored in this register. D7 N/A 1 D6 N/A D5 N/A D4 01 D3 N/A D2 N/A D1 N/A D0 N/A Default settings at power-up. Table 14. Interrupt Status 2 Register Bit Descriptions Bit D4 Function 1 when VDD value is greater than the corresponding VHIGH limit. 1 when VDD is less than or equal to the corresponding VLOW limit. D7 V9 X1 1 D6 V8 X1 D5 V7 X1 D4 V6 X1 D3 V5 X1 D2 V4 X1 D1 V3 X1 D0 V2 X1 Loaded with VDD value after power-up. Table 20. Internal Temperature Value MSBs D7 T9 01 1 D6 T8 01 D5 T7 01 Default settings at power-up. Internal Temperature Value/VDD Value Register LSBs (Read-Only) [Address 0x03] This 8-bit, read-only register stores the 2 LSBs of the 10-bit temperature reading from the internal temperature sensor and the 2 LSBs of the 10-bit supply voltage reading. Rev. B | Page 28 of 44 D4 T6 01 D3 T5 01 D2 T4 01 D1 T3 01 D0 T2 01 ADT7316/ADT7317/ADT7318 External Temperature Value Register MSBs (Read-Only) [Address 0x08] This 8-bit, read-only register stores the external temperature value from the external temperature sensor in twos complement format. The 8 MSBs of the 10-bit value are stored in this register. Table 26. DAC B (ADT7317) LSBs Table 21. External Temperature Value MSBs DAC B Register MSBs (Read/Write) [Address 0x13] This 8-bit read/write register contains the 8 MSBs of the DAC B word. The value in this register is combined with the value in the DAC B register LSBs and converted to an analog voltage on the VOUT-B pin. On power-up, the voltage output on the VOUT-B pin is 0 V. D7 T9 01 1 D6 T8 01 D5 T7 01 D4 T6 01 D3 T5 01 D2 T4 01 D1 T3 01 D0 T2 01 Default settings at power-up. DAC A Register LSBs (Read/Write) [Address 0x10] This 8-bit read/write register contains the 4/2 LSBs of the ADT7316/ADT7317 DAC A word, respectively. The value in this register is combined with the value in the DAC A Register MSBs and converted to an analog voltage on the VOUT-A pin. On power-up, the voltage output on the VOUT-A pin is 0 V. Table 22. DAC A (ADT7316) LSBs D7 B3 01 1 D6 B2 01 D5 B1 01 D4 LSB 01 D3 N/A N/A D2 N/A N/A D1 N/A N/A D0 N/A N/A D1 N/A N/A D0 N/A N/A Default settings at power-up. Table 23. DAC A (ADT7317) LSBs D7 B1 01 1 D6 LSB 01 D5 N/A N/A D4 N/A N/A D3 N/A N/A D2 N/A N/A Default settings at power-up. DAC A Register MSBs (Read/Write) [Address 0x11] This 8-bit read/write register contains the 8 MSBs of the DAC A word. The value in this register is combined with the value in the DAC A Register LSBs and converted to an analog voltage on the VOUT-A pin. On power-up, the voltage output on the VOUT-A pin is 0 V. 1 D6 B8 01 D5 B7 01 D4 B6 01 D3 B5 01 D2 B4 01 D1 B3 01 D0 B2 01 Default settings at power-up. DAC B Register LSBs (Read/Write) [Address 0x12] This 8-bit read/write register contains the 4/2 LSBs of the ADT7316/ADT7317 DAC B word, respectively. The value in this register is combined with the value in the DAC B register MSBs and converted to an analog voltage on the VOUT-B pin. On power-up, the voltage output on the VOUT-B pin is 0 V. 1 D6 B2 01 D5 B1 01 D4 LSB 01 D3 N/A N/A D2 N/A N/A D1 N/A N/A D6 LSB 01 D5 N/A N/A D4 N/A N/A D3 N/A N/A D2 N/A N/A D1 N/A N/A D0 N/A N/A Default settings at power-up. Table 27. DAC B MSBs D7 MSB 01 1 D6 B8 01 D5 B7 01 D4 B6 01 D3 B5 01 D2 B4 01 D1 B3 01 D0 B2 01 Default settings at power-up. DAC C Register LSBs (Read/Write) [Address 0x14] This 8-bit read/write register contains the 4/2 LSBs of the ADT7316/ADT7317 DAC C word, respectively. The value in this register is combined with the value in the DAC C register MSBs and converted to an analog voltage on the VOUT-C pin. On power-up, the voltage output on the VOUT-C pin is 0 V. Table 28. DAC C (ADT7316) LSBs D7 B3 01 1 D6 B2 01 D5 B1 01 D4 LSB 01 D3 N/A N/A D2 N/A N/A D1 N/A N/A D0 N/A N/A D1 N/A N/A D0 N/A N/A Default settings at power-up. Table 29. DAC C (ADT7317) LSBs D7 B1 01 D6 LSB 01 D5 N/A N/A D4 N/A N/A D3 N/A N/A D2 N/A N/A Default settings at power-up. DAC C Register MSBs (Read/Write) [Address 0x15] This 8-bit read/write register contains the 8 MSBs of the DAC C word. The value in this register is combined with the value in the DAC C register LSBs and converted to an analog voltage on the VOUT-C pin. On power-up, the voltage output on the VOUT-C pin is 0 V. Table 30. DAC C MSBs D7 MSB 01 1 Table 25. DAC B (ADT7316) LSBs D7 B3 01 1 1 Table 24. DAC A MSBs D7 MSB 01 D7 B1 01 D6 B8 01 D5 B7 01 Default settings at power-up. D0 N/A N/A Default settings at power-up. Rev. B | Page 29 of 44 D4 B6 01 D3 B5 01 D2 B4 01 D1 B3 01 D0 B2 01 ADT7316/ADT7317/ADT7318 DAC D Register LSBs (Read/Write) [Address 0x16] This 8-bit read/write register contains the 4/2 LSBs of the ADT7316/ADT7317 DAC D word, respectively. The value in this register is combined with the value in the DAC D register MSBs and converted to an analog voltage on the VOUT-D pin. On power-up, the voltage output on the VOUT-D pin is 0 V. Table 35. Control Configuration 1 Bit Descriptions Bit C0 Table 31. DAC D (ADT7316) LSBs D7 B3 01 1 D6 B2 01 D5 B1 01 D4 LSB 01 D3 N/A N/A D2 N/A N/A D1 N/A N/A D0 N/A N/A C1:4 C5 C6 Default settings at power-up. PD Table 32. DAC D (ADT7317) LSBs D7 B1 01 1 D6 LSB 01 D5 N/A N/A D4 N/A N/A D3 N/A N/A D2 N/A N/A D1 N/A N/A D0 N/A N/A Default settings at power-up. DAC D Register MSBs (Read/Write) [Address 0x17] This 8-bit read/write register contains the 8 MSBs of the DAC D word. The value in this register is combined with the value in the DAC D register LSBs and converted to an analog voltage on the VOUT-D pin. On power-up, the voltage output on the VOUT-D pin is 0 V. Table 33. DAC D MSBs D7 MSB 01 1 D6 B8 01 D5 B7 01 D4 B6 01 D3 B5 01 D2 B4 01 D1 B3 01 D0 B2 01 Default settings at power-up. Control Configuration 1 Register (Read/Write) [Address 0x18] This configuration register is an 8-bit read/write register that is used to setup some of the operating modes of the ADT7316/ ADT7317/ADT7318. Table 34. Control Configuration 1 D7 PD 01 1 D6 C6 01 D5 C5 01 Default settings at power-up. D4 C4 01 D3 C3 01 D2 C2 01 D1 C1 01 D0 C0 01 Function This bit enables/disables conversions in round robin mode and single-channel mode. The ADT7316/ADT7317/ ADT7318 power up in round-robin mode, but monitoring is not initiated until this bit is set. 0 = Stop monitoring (default). 1 = Start monitoring. Reserved. Only write 0s. 0 = Enable INT/INT output. 1 = Disable INT/INT output. Configures INT/INT output polarity. 0 = Active low. 1 = Active high. Power-Down Bit. Setting this bit to 1 puts the ADT7316/ ADT7317/ADT7318 into standby mode. In this mode, both the ADC and the DACs are fully powered down, but the serial interface is still operational. To power up the part again, write 0 to this bit. Control Configuration 2 Register (Read/Write) [Address 0x19] This configuration register is an 8-bit, read/write register that is used to set up some of the operating modes of the ADT7316/ ADT7317/ADT7318. Table 36. Control Configuration 2 D7 C7 01 1 D6 C6 01 D5 C5 01 D4 C4 01 D3 C3 01 D2 C2 01 D1 C1 01 D0 C0 01 Default settings at power-up. Table 37. Control Configuration 2 Bit C0:1 C2:3 C4 C5 C6 C7 Rev. B | Page 30 of 44 Function In single-channel mode, these bits select between VDD, the internal temperature sensor, and the external temperature sensor for conversion. 00 = VDD (default). 01 = Internal temperature sensor. 10 = External temperature sensor. 11 = Reserved. Reserved. Selects between single-channel and round robin conversion cycle. Default is round robin. 0 = Round robin. 1 = Single channel. Default condition is to average every measurement on all channels 16 times. This bit disables this averaging. Channels affected are temperature and VDD. 0 = Enable averaging. 1 = Disable averaging. SMBus timeout on the serial clock puts a 25 ms limit on the pulse width of the clock. Ensures that a fault on the master SCL does not lock up the SDA line. SMBus timeout. 0 = Disable. 1 = Enable SMBus timeout. Software reset. Setting this bit to 1 causes a software reset. All registers and DAC outputs reset to their default settings. ADT7316/ADT7317/ADT7318 Control Configuration 3 Register (Read/Write) [Address 0x1A] This configuration register is an 8-bit read/write register that is used to set up some of the operating modes of the ADT7316/ ADT7317/ADT7318. Table 41. DAC Configuration Bit D0 D1 Table 38. Control Configuration 3 D7 C7 01 1 D6 C6 01 D5 C5 01 D4 C4 01 D3 C3 01 D2 C2 01 D1 C1 01 D0 C0 01 D2 D3 Default settings at power-up. Table 39. Control Configuration 3 Bit C0 C1 C2 C3 C4 C5 C6 C7 Function Selects between fast and normal ADC conversion speeds for all three monitoring channels. 0 = ADC clock at 1.4 kHz. 1 = ADC clock at 22.5 kHz. D+ and D− analog filters are disabled. On the ADT7316 and ADT7317, this bit selects between 8-bit and 10-bit DAC output resolution on the thermal voltage output feature. Default = 8 bits. This bit has no effect on the ADT7318 output because this part has only an 8-bit DAC. In the ADT7318 case, write 0 to this bit. 0 = 8-bit resolution. 1 = 10-bit resolution. Reserved. Only write 0. 0 = LDAC pin controls updating of DAC outputs. 1 = DAC configuration register and LDAC configuration register control the updating of the DAC outputs. Reserved. Only write 0. Setting this bit selects DAC A voltage output to be proportional to the internal temperature measurement. Setting this bit selects DAC B voltage output to be proportional to the external temperature measurement. Reserved. Only write 0. DAC Configuration Register (Read/Write) [Address 0x1B] This configuration register is an 8-bit, read/write register that is used to control the output ranges of all four DACs and to control the loading of the DAC registers if the LDAC pin is disabled (Bit C3 = 1, Control Configuration 3 register). 1 D6 D6 01 D5 D5 01 D4 D4 01 D6 D7 LDAC Configuration Register (Write-Only) [Address 0x1C] This configuration register is an 8-bit write register that is used to control the updating of the quad DAC outputs if the LDAC pin is disabled and Bit D4 and Bit D5 of the DAC Configuration register are both set to 1. It also selects either the internal or external VREF for all four DACs. Bit D0 to Bit D3 in this register are self-clearing, that is, reading back from this register always gives 0s for these bits. Table 42. LDAC Configuration D7 D7 01 1 D6 D6 01 D5 D5 01 D4 D4 01 D3 D3 01 D2 D2 01 D1 D1 01 D0 D0 01 Default settings at power-up. Table 43. LDAC Configuration Table 40. DAC Configuration D7 D7 01 D4:5 Function Selects the output range of DAC A. 0 = 0 V to VREF. 1 = 0 V to 2 VREF. Selects the output range of DAC B. 0 = 0 V to VREF. 1 = 0 V to 2 VREF. Selects the output range of DAC C. 0 = 0 V to VREF. 1 = 0 V to 2 VREF. Selects the output range of DAC D. 0 = 0 V to VREF. 1 = 0 V to 2 VREF. 00 = MSB write to any DAC register generates an LDAC command, which updates that DAC only. 01 = MSB write to DAC B or DAC D register generates an LDAC command, which updates DAC A, DAC B or DAC C, DAC D, respectively. 10 = MSB write to DAC D register generates an LDAC command, which updates all 4 DACs. 11 = LDAC command generated from LDAC register. Setting this bit allows the external VREF to bypass the reference buffer when supplying DAC A and DAC B. Setting this bit allows the external VREF to bypass the reference buffer when supplying DAC C and DAC D. D3 D3 01 D2 D2 01 D1 D1 01 D0 D0 01 Bit D0 D1 Default settings at power-up. D2 D3 D4 D5:D7 Rev. B | Page 31 of 44 Function Writing 1 to this bit generates the LDAC command to update the DAC A output only. Writing 1 to this bit generates the LDAC command to update the DAC B output only. Writing 1 to this bit generates the LDAC command to update the DAC C output only. Writing 1 to this bit generates the LDAC command to update the DAC D output only. Selects either internal VREF or external VREF-AB for DAC A, DAC B, DAC C and DAC D. 0 = External VREF. 1 = Internal VREF. Reserved. Only write 0s. ADT7316/ADT7317/ADT7318 Interrupt Mask 1 Register (Read/Write) [Address 0x1D] This mask register is an 8-bit, read/write register that can be used to mask out any interrupts that can cause the INT/INT pin to go active. Table 48. Internal Temperature Offset D7 D7 01 1 Table 44. Interrupt Mask 1 D7 D7 01 1 D6 D6 01 D5 D5 01 D4 D4 01 D3 D3 01 D2 D2 01 D1 D1 01 D0 D0 01 Default settings at power-up. Table 45. Interrupt Mask 1 Bit Descriptions Bit D0 D1 D2 D3 D4 D5: 7 Function 0 = Enable internal THIGH interrupt. 1 = Disable internal THIGH interrupt. 0 = Enable internal TLOW interrupt. 1 = Disable internal TLOW interrupt. 0 = Enable external THIGH interrupt. 1 = Disable external THIGH interrupt. 0 = Enable external TLOW interrupt. 1 = Disable external TLOW interrupt. 0 = Enable external temperature fault interrupt. 1 = Disable external temperature fault interrupt. Reserved. Only write 0s. 1 D4 D4 01 D3 D3 01 D2 D2 01 D1 D1 01 D0 D0 01 Default settings at power-up. Table 47. Interrupt Mask 2 Bit Descriptions Bit D0:D3 D4 D5:7 D3 D3 01 D2 D2 01 D1 D1 01 D0 D0 01 Default settings at power-up. D7 D7 01 Table 46. Interrupt Mask 2 D5 D5 01 D4 D4 01 Table 49. External Temperature Offset Interrupt Mask 2 Register (Read/Write) [Address 0x1E] This mask register is an 8-bit read/write register that can be used to mask out any interrupts that can cause the INT/INT pin to go active. D6 D6 01 D5 D5 01 External Temperature Offset Register (Read/Write) [Address 0x20] This register contains the offset value for the external temperature channel. A twos complement number can be written to this register which is then added to the measured result before it is stored or compared to limits. In this way, one-point calibration can be done whereby the whole transfer function of the channel can be moved up or down. From a software point of view, this may be a very simple method to vary the characteristics of the measurement channel if the thermal characteristics change. As it is an 8-bit register, the temperature resolution is 1°C. 1 D7 D7 01 D6 D6 01 Function Reserved. Only write 0s. 0 = Enable VDD interrupts. 1 = Disable VDD interrupts. Reserved. Only write 0s. D6 D6 01 D5 D5 01 D4 D4 01 D3 D3 01 D2 D2 01 D1 D1 01 D0 D0 01 Default settings at power-up. Internal Analog Temperature Offset Register (Read/Write) [Address 0x21] This register contains the offset value for the internal thermal voltage output. A twos complement number can be written to this register which is then added to the measured result before it is converted by DAC A. Varying the value in this register has the effect of varying the temperature span. For example, the output voltage can represent a temperature span of −128°C to +127°C or even 0°C to 127°C. In essence, this register changes the position of 0 V on the temperature scale. Anything other than −128°C to +127°C produces an upper dead band on the DAC A output. As it is an 8-bit register, the temperature resolution is 1°C. The default value is −40°C. Table 50. Internal Analog Temperature Offset D7 D7 11 Internal Temperature Offset Register (Read/Write) [Address 0x1F] This register contains the offset value for the internal temperature channel. A twos complement number can be written to this register which is then added to the measured result before it is stored or compared to limits. In this way, a one-point calibration can be done whereby the whole transfer function of the channel can be moved up or down. From a software point of view, this may be a very simple method to vary the characteristics of the measurement channel if the thermal characteristics change. As it is an 8-bit register, the temperature resolution is 1°C. 1 D6 D6 11 D5 D5 01 Default settings at power-up. Rev. B | Page 32 of 44 D4 D4 11 D3 D3 11 D2 D2 01 D1 D1 01 D0 D0 01 ADT7316/ADT7317/ADT7318 External Analog Temperature Offset Register (Read/Write) [Address 0x22] This register contains the offset value for the external thermal voltage output. A twos complement number can be written to this register which is then added to the measured result before it is converted by DAC B. Varying the value in this register has the affect of varying the temperature span. For example, the output voltage can represent a temperature span of −128°C to +127°C or even 0°C to 127°C. In essence, this register changes the position of 0 V on the temperature scale. Anything other than −128°C to +127°C produces an upper dead band on the DAC B output. As it is an 8-bit register, the temperature resolution is 1°C. The default value is −40°C. Table 51. External Analog Temperature D7 D7 11 1 D6 D6 11 D5 D5 01 D4 D4 11 D3 D3 11 D2 D2 01 D1 D1 01 D0 D0 01 Default settings at power-up. VDD VHIGH Limit Register (Read/Write) [Address 0x23] This limit register is an 8-bit read/write register that stores the VDD upper limit that causes an interrupt and activates the INT/ INT output (if enabled). For this to happen, the measured VDD value has to be greater than the value in this register. The default value is 5.46 V. Internal THIGH Limit Register (Read/Write) [Address 0x25] This limit register is an 8-bit read/write register that stores the twos complement of the internal temperature upper limit that causes an interrupt and activates the INT/INT output (if enabled). For this to happen, the measured internal temperature value has to be greater than the value in this register. As it is an 8-bit register, the temperature resolution is 1°C. The default value is 100°C. Positive Temperature = Limit Register Code (dec) Negative Temperature = Limit Register Code (dec) – 256 Table 54. Internal THIGH Limit D7 D7 01 1 1 D6 D6 11 D5 D5 01 D4 D4 01 D3 D3 01 D2 D2 11 D1 D1 11 D0 D0 11 Default settings at power-up. VDD VLOW Limit Register (Read/Write) [Address 0x24] This limit register is an 8-bit read/write register that stores the VDD lower limit that causes an interrupt and activates the INT/ INT output (if enabled). For this to happen, the measured VDD value has to be less than or equal to the value in this register. The default value is 2.7 V. Table 53. VDD VLOW Limit D7 D7 01 1 D6 D6 11 D5 D5 11 D4 D4 01 D3 D3 01 D2 D2 01 D1 D1 11 D0 D0 01 D5 D5 11 D4 D4 01 D3 D3 01 D2 D2 11 D1 D1 01 D0 D0 01 Default settings at power-up. Internal TLOW Limit Register (Read/Write) [Address 0x26] This limit register is an 8-bit, read/write register that stores the twos complement of the internal temperature lower limit that causes an interrupt and activates the INT/INT output (if enabled). For this to happen, the measured internal temperature value has to be more negative than or equal to the value in this register. As it is an 8-bit register, the temperature resolution is 1°C. The default value is −55°C. Positive Temperature = Limit Register Code (dec) Negative Temperature = Limit Register Code (dec) – 256 Table 52. VDD VHIGH Limit D7 D7 11 D6 D6 11 Table 55. Internal TLOW Limit D7 D7 11 1 D6 D6 11 D5 D5 01 D4 D4 01 D3 D3 11 D2 D2 01 D1 D1 01 D0 D0 11 Default settings at power-up. External THIGH Limit Register (Read/Write) [Address 0x27] This limit register is an 8-bit, read/write register that stores the twos complement of the external temperature upper limit that causes an interrupt and activates the INT/INT output (if enabled). For this to happen, the measured external temperature value has to be greater than the value in this register. As it is an 8-bit register, the temperature resolution is 1°C. The default value is −1°C. Positive Temperature = Limit Register Code (dec) Negative Temperature = Limit Register Code (dec) – 256 Default settings at power-up. Table 56. External THIGH Limit D7 D7 11 1 D6 D6 11 D5 D5 11 Default settings at power-up. Rev. B | Page 33 of 44 D4 D4 11 D3 D3 11 D2 D2 11 D1 D1 11 D0 D0 11 ADT7316/ADT7317/ADT7318 Manufacturer’s ID Register (Read-Only) [Address 0x4E] This register contains the manufacturers identification number. Analog Devices, Inc.’s ID is 0x41. External TLOW Limit Register (Read/Write) [Address 0x28] This limit register is an 8-bit, read/write register that stores the twos complement of the external temperature lower limit that causes an interrupt and activates the INT/INT output (if enabled). For this to happen, the measured external temperature value has to be more negative than or equal to the value in this register. As it is an 8-bit register, the temperature resolution is 1°C. The default value is 0°C. Silicon Revision Register (Read-Only) [Address 0x4F] This register is divided into the 4 LSBs representing the stepping and the 4 MSBs representing the version. The stepping contains the manufacturer’s code for minor revisions or steppings to the silicon. The version is the ADT7316/ADT7317/ ADT7318 version number. Positive Temperature = Limit Register Code (dec) Negative Temperature = Limit Register Code (dec) – 256 SPI Lock Status Register (Read-Only) [Address 0x7F] Bit D0 (LSB) of this read-only register indicates whether the SPI interface is locked. Writing to this register causes the device to malfunction. The default value is 0x00. Table 57. External TLOW Limit D7 D7 01 1 D6 D6 01 D5 D5 01 D4 D4 01 D3 D3 01 D2 D2 01 D1 D1 01 D0 D0 01 0 = I2C interface. 1 = SPI interface selected and locked. Default settings at power-up. Device ID Register (Read-Only) [Address 0x4D] This 8-bit, read-only register indicates which part the device is in the model range. ADT7316 = 0x01, ADT7317 = 0x09, and ADT7318 = 0x05. VDD ADT7316/ ADT7317/ ADT7318 VDD 10kΩ 10kΩ CS SDA I2C ADDRESS = 1001 000 02661-049 SCL ADD Figure 48. Typical I2C Interface Connection ADT7316/ ADT7317/ ADT7318 LOCK AND SELECT SPI CS VDD 820Ω 820Ω 820Ω SPI FRAMING EDGE DIN 02661-050 SCLK DOUT Figure 49. Typical SPI Interface Connection Rev. B | Page 34 of 44 ADT7316/ADT7317/ADT7318 A CS (START HIGH) C B SPI LOCKED ON THIRD RISING EDGE A SPI FRAMING EDGE C B SPI LOCKED ON THIRD RISING EDGE 02661-048 CS (START LOW) SPI FRAMING EDGE Figure 50. Serial Interface—Selecting and Locking SPI Protocol 1 9 1 9 SCL 1 0 0 1 A2 A1 START BY MASTER A0 R/W P7 P6 ACKNOWLEDGE BY ADT7316/ADT7317/ADT7318 FRAME 1 SERIAL BUS ADDRESS BYTE P5 P4 P3 P2 P1 P0 ACKNOWLEDGE BY ADT7316/ADT7317/ADT7318 FRAME 2 ADDRESS POINTER REGISTER BYTE Figure 51. I2C—Writing to the Address Pointer Register to Select a Register for a Subsequent Read Operation Rev. B | Page 35 of 44 STOP BY MASTER 02661-051 SDA ADT7316/ADT7317/ADT7318 SERIAL INTERFACE There are two serial interfaces that can be used on this part, the I2C and the SPI interface. The device powers up with the serial interface in I2C mode, but it is not locked into this mode. To stay in I2C mode, it is recommended that the user ties the CS line to either VCC or GND. It is not possible to lock the I2C mode, but it is possible to select and lock the SPI mode. calculated using CRC-8. The frame clock sequence (FCS) conforms to CRC-8 by the polynomial: To select and lock the interface into the SPI mode, a number of pulses must be sent down the CS (Pin 4) line. The following section describes how this is done. 1. The master initiates data transfer by establishing a start condition, defined as a high-to-low transition on the serial data line SDA while the serial clock line SCL remains high. This indicates that an address/data stream follow. All slave peripherals connected to the serial bus respond to the start condition and shift in the next 8 bits, consisting of a 7-bit address (MSB first) plus an R/W bit, which determines the direction of the data transfer, that is, whether data is to be written to or read from the slave device. The peripheral whose address corresponds to the transmitted address responds by pulling the data line low during the low period before the ninth clock pulse, known as the acknowledge bit. All other devices on the bus now remain idle, while the selected device waits for data to be read from or written to it. If the R/W bit is 0, the master writes to the slave device. If the R/W bit is 1, the master reads from the slave device. 2. Data is sent over the serial bus in sequences of nine clock pulses, 8 bits of data followed by an acknowledge bit from the receiver of data. Transitions on the data line must occur during the low period of the clock signal and remain stable during the high period, because a low-to-high transition when the clock is high may be interpreted as a stop signal. 3. When all data bytes have been read or written, stop conditions are established. In write mode, the master pulls the data line high during the 10th clock pulse to assert a stop condition. In read mode, the master device pulls the data line high during the low period before the ninth clock pulse. This is known as no acknowledge. The master takes the data line low during the low period before the 10th clock pulse, then high during the 10th clock pulse to assert a stop condition. C(x) = x8 + x2 + x1 + 1 Consult SMBus for more information. The serial bus protocol operates as follows: Once the SPI communication protocol has been locked in, it cannot be unlocked while the device is still powered up. Bit D0 of the SPI Lock Status register (Address 0x7F) is set to 1 when a successful SPI interface lock has been accomplished. To reset the serial interface, the user must power down the part and power up again. A software reset does not reset the serial interface. SERIAL INTERFACE SELECTION The CS line controls the selection between I2C and SPI. Figure 50 shows the selection process necessary to lock the SPI interface mode. To communicate to the ADT7316/ADT7317/ADT7318 using the SPI protocol, send three pulses down the CS line, as shown in Figure 50. On the third rising edge (marked as C in Figure 50), the part selects and locks the SPI interface. The user is limited to communicating to the device using the SPI protocol. As per most SPI standards, the CS line must be low during every SPI communication to the ADT7316/ADT7317/ ADT7318 and high all other times. Typical examples of how to connect the dual interface as I2C or SPI are shown in Figure 48 and Figure 49. The following sections describe in detail how to use the I2C and SPI protocols associated with the ADT7316/ADT7317/ ADT7318. I2C SERIAL INTERFACE Like all I2C-compatible devices, the ADT7316/ADT7317/ ADT7318 have a 7-bit serial address. The 4 MSBs of this address for the ADT7316/ADT7317/ADT7318 are set to 1001. The 3 LSBs are set by Pin 11, ADD. The ADD pin can be configured three ways to give three different address options: low, floating, and high. Setting the ADD pin low gives a serial bus address of 1001 000, leaving it floating gives the address 1001 010, and setting it high gives the address 1001 011. The recommended pull-up resistor value is 10 kΩ. There is a programmable SMBus timeout. When this is enabled the SMBus times out after 25 ms of no activity. To enable it, set Bit 6 of the Control Configuration 2 register (Address 0x19). The power-up default is with the SMBus timeout disabled. The ADT7316/ADT7317/ADT7318 support SMBus packet error checking (PEC) and its use is optional. It is triggered by supplying the extra clocks for the PEC byte. The PEC byte is Any number of bytes of data may be transferred over the serial bus in one operation. However, reads and writes cannot be mixed in one operation because the type of operation is determined at the beginning and cannot subsequently be changed without starting a new operation. The I2C address set up by the ADD pin is not latched by the device until after this address has been sent twice. On the eighth SCL cycle of the second valid communication, the serial bus address is latched in. This is the SCL cycle directly after the device has seen its own I2C serial bus address. Any subsequent changes on this pin have no effect on the I2C serial bus address. Rev. B | Page 36 of 44 ADT7316/ADT7317/ADT7318 Writing to the ADT7316/ADT7317/ADT7318 SPI SERIAL INTERFACE Depending on the register being written to, there are two different writes for the ADT7316/ADT7317/ADT7318. It is not possible to do a block write to this part, that is, no I2C auto-increment. The SPI serial interface of the ADT7316/ADT7317/ADT7318 consists of four wires, CS, SCLK, DIN, and DOUT. The CS is used to select the device when more than one device is connected to the serial clock and data lines. The CS is also used to distinguish between any two separate serial communications (see Figure 58). The SCLK is used to clock data in and out of the part. The DIN line is used to write to the registers and the DOUT line is used to read data back from the registers. The recommended pull-up resistor value is between 500 Ω to 820 Ω. Strong pull ups are needed when serial clock speeds (which are close to the maximum limit) are used or when the SPI interface lines are experiencing large capacitive loading. Larger resistor values can be used for pull-up resistors when the serial clock speed is reduced. Writing to the Address Pointer Register for a Subsequent Read To read data from a particular register, the address pointer register must contain the address of that register. If it does not, the correct address must be written to the address pointer register by performing a single-byte write operation, as shown in Figure 51. The write operation consists of the serial bus address followed by the address pointer byte. No data is written to any of the data registers. A read operation is then performed to read the register. The part operates in slave mode and requires an externally applied serial clock to the SCLK input. The serial interface is designed to allow the part to be interfaced to systems that provide a serial clock that is synchronized to the serial data. Writing Data to a Register All registers are 8-bit registers so only one byte of data can be written to each register. Writing a single byte of data to one of these read/write registers consists of the serial bus address, the data register address written to the address pointer register, followed by the data byte written to the selected data register. This is illustrated in Figure 52. To write to a different register, another start or repeated start is required. If more than one byte of data is sent in one communication operation, the addressed register is repeatedly loaded until the last data byte is sent. There are two types of serial operations, a read and a write. Command words are used to distinguish between a read and a write operation, as shown in Table 58. Address auto-increment is possible in SPI mode. Table 58. SPI Command Words Write 0x90 (1001 0000) Read 0x91 (1001 0001) Reading Data from the ADT7316/ADT7317/ADT7318 Reading data from the ADT7316/ADT7317/ADT7318 is done in a 1-byte operation. Reading back the contents of a register is shown in Figure 56. The register address previously had been set up by a single byte write operation to the address pointer register. To read from another register, write to the address pointer register again to set up the relevant register address. Therefore, block reads are not possible, that is, no I2C autoincrement. 1 9 1 9 SCL 1 0 0 1 A2 A1 START BY MASTER A0 P7 R/W P6 P5 P4 P3 ACKNOWLEDGE BY ADT7316/ADT7317/ADT7318 P2 P1 P0 ACKNOWLEDGE BY ADT7316/ADT7317/ADT7318 FRAME 1 SERIAL BUS ADDRESS BYTE FRAME 2 ADDRESS POINTER REGISTER BYTE 1 9 SCL (CONTINUED) SDA (CONTINUED) D7 D6 D5 D4 D3 D2 D1 D0 ACKNOWLEDGE BY STOP BY ADT7316/ADT7317/ADT7318 MASTER FRAME 3 DATA BYTE Figure 52. I2C—Writing to the Address Pointer Register Followed by a Single Byte of Data to the Selected Register Rev. B | Page 37 of 44 02661-052 SDA ADT7316/ADT7317/ADT7318 Write Operation time. In Figure 54, the register address section provides the first register address that is written to. Subsequent data bytes are written into sequential writable registers. Therefore, after each data byte has been written into a register, the address pointer register auto-increments its value to the next available register. The address pointer register auto-increments from Address 0x00 to Address 0x3F and loops back to start all over again at Address 0x00 when it reaches Address 0x3F. Figure 54 and Figure 55 show the timing diagrams for a write operation to the ADT7316/ADT7317/ADT7318. Data is clocked into the registers on the rising edge of SCLK. When the CS line is high, the DIN and DOUT lines are in three-state mode. Only when the CS goes from a high to a low does the part accept any data on the DIN line. In SPI mode, the address pointer register is capable of an auto-increment to the next register in the register map without having to load the address pointer register each 1 9 1 9 SCL 1 0 0 1 A2 A1 A0 R/W D7 D6 D5 D4 D3 D2 ACKNOWLEDGE BY ADT7316/ADT7317/ADT7318 START BY MASTER FRAME 1 SERIAL BUS ADDRESS BYTE D1 D0 NO ACKNOWLEDGE BY STOP BY MASTER MASTER FRAME 2 SINGLE DATA BYTE FROM ADT7316/ADT7317/ADT7318 02661-053 SDA Figure 53. I2C — Reading a Single Byte of Data From a Selected Register CS 1 8 8 1 SCLK DIN D6 D7 D5 D3 D4 D2 D1 D7 D0 D6 D5 D4 D3 D2 D1 D0 START WRITE COMMAND REGISTER ADDRESS CS (CONTINUED) 1 8 SCLK (CONTINUED) D7 DIN (CONTINUED) D6 D3 D4 D5 D1 D2 D0 02661-054 STOP DATA BYTE Figure 54. SPI—Writing to the Address Pointer Register Followed by a Single Byte of Data to the Selected Register CS 1 8 8 1 SCLK D7 D6 D5 D4 D3 D2 D1 D0 D7 D6 D5 D4 D3 D2 D1 D0 STOP START WRITE COMMAND REGISTER ADDRESS Figure 55. SPI—Writing to the Address Pointer Register to Select a Register for a Subsequent Read Operation Rev. B | Page 38 of 44 02661-055 DIN ADT7316/ADT7317/ADT7318 CS 1 8 8 1 SCLK DIN D7 D6 D5 D4 D3 D2 D1 D0 X X X X X X X X DOUT X X X X X X X X D7 D6 D5 D4 D3 D2 D1 D0 STOP READ COMMAND 02661-056 START DATA BYTE 1 Figure 56. SPI —Reading a Single Byte of Data From a Selected Register CS 1 8 8 1 SCLK DIN D7 D6 D5 D4 D3 D2 D1 D0 X X X X X X X X DOUT X X X X X X X X D7 D6 D5 D4 D3 D2 D1 D0 START DATA BYTE 1 READ COMMAND CS (CONTINUED) 1 8 SCLK (CONTINUED) DIN (CONTINUED) DOUT (CONTINUED) X X X X X X X X D7 D6 D5 D4 D3 D2 D1 D0 02661-057 STOP DATA BYTE 2 Figure 57. SPI—Reading Two Bytes of Data From Two Sequential Registers SPI READ OPERATION WRITE OPERATION 02661-058 CS Figure 58. SPI—Correct Use of CS During SPI Communication Read Operation Figure 56 and Figure 57 show the timing diagrams necessary to accomplish correct read operations. To read back from a register, first write to the address pointer register with the address of the register to read from, as shown in Figure 53. Figure 56 shows the procedure for reading back a single byte of data. The read command is first sent to the part during the first eight clock cycles. As the read command is being sent, irrelevant data is output onto the DOUT line. During the following eight clock cycles, the data contained in the register selected by the address pointer register is output onto the DOUT line. Data is output onto the DOUT line on the falling edge of SCLK. Figure 57 shows the procedure when reading data from two sequential registers. Multiple data reads are possible in SPI interface mode as the address pointer register is auto-incremental. The address pointer register auto-increments from Address 0x00 to Address 0x3F and loops back to start all over again at Address 0x00 when it reaches Address 0x3F. Rev. B | Page 39 of 44 ADT7316/ADT7317/ADT7318 The ADT7316/ADT7317/ADT7318 INT/INT output is an interrupt line that signals an over-limit/under-limit event on any of the measurement channels if the interrupt on that event has not been disabled. The ADT7316/ADT7317/ADT7318 are slave-only devices and use the SMBus/SPI INT/INT as their only means to signal other devices that an event has occurred. The INT/INT pin has an open-drain configuration that allows the outputs of several devices to be wire-AND’ed together when the INT/INT pin is active low. Use C6 of the Control Configuration 1 register (Address 0x18) to set the active polarity of the INT/INT output. The power-up default is active low. The INT/ INT output can be disabled or enabled by setting C5 of the Control Configuration 1 register (Address 0x18) to 1 or 0, respectively. One or more INT/INT outputs can be connected to a common SMBALERT line connected to the master. When a SMBALERT line is pulled low by one of the devices, the following procedure occurs (see Figure 59). MASTER RECEIVES SMBALERT START ALERT RESPONSE ADDRESS RD ACK DEVICE ADDRESS MASTER SENDS ARA AND READ COMMAND NO STOP ACK 02661-059 SMBUS/SPI INT/INT DEVICE SENDS ITS ADDRESS Figure 59. INT/INT Responds to SMBALERT ARA 1. SMBALERT is pulled low. 2. The master initiates a read operation and sends the alert response address (ARA = 0001 100). This is a general call address that must not be used as a specific device address. The INT/INT output becomes active when either the internal temperature value, the external temperature value, or the VDD value exceeds the values in their corresponding THIGH/VHIGH or TLOW/VLOW registers. The INT/INT output goes inactive again when a conversion result indicates that all measurement channels are within their trip limits, and when the status register associated with the out-of-limit event is read. The two interrupt status registers show which event caused the INT/INT pin to go active. 3. The devices whose INT/INT output is low respond to the alert response address and the master reads its device address. Because the device address is 7 bits long, an LSB of 1 is added. The address of the device is now known and it can be interrogated in the usual way. The INT/INT output requires an external pull-up resistor. This can be connected to a voltage different from VDD provided that the maximum voltage rating of the INT/INT output pin is not exceeded. The value of the pull-up resistor depends on the application but should be large enough to avoid excessive sink currents at the INT/INT output, which can heat the chip and affect the temperature reading. 5. Once the ADT7316/ADT7317/ADT7318 has responded to the alert response address, it resets its INT/INT output, provided that the condition that caused the out-of-limit event no longer exists and the status register associated with the out-of-limit event is read. If the SMBALERT line remains low, the master sends the ARA again. It continues to do this until all devices whose SMBALERT outputs were low have responded. The INT/INT pin behaves the same way as a SMBus alert pin when the SMBus/I2C interface is selected. It is an open-drain output and requires a pull-up to VDD. Several INT/INT outputs can be wire-AND’ed together so that the common line goes low if one or more of the INT/INT outputs goes low. The polarity of the INT/INT pin must be set for active low for a number of outputs to be wire-AND’ed together. The INT/INT output can operate as a SMBALERT function. Slave devices on the SMBus typically cannot signal to the master that they want to talk, but the SMBALERT function allows them to do so. SMBALERT is used in conjunction with the SMBus general call address. MASTER RECEIVES SMBALERT START Rev. B | Page 40 of 44 ALERT RESPONSE ADDRESS MASTER SENDS ARA AND READ COMMAND DEVICE ACK DEVICE RD ACK ADDRESS MASTER ACK ACK MASTER NACK PEC NO ACK DEVICE SENDS DEVICE SENDS ITS ADDRESS ITS PEC DATA Figure 60. INT/INT Responds to SMBALERT ARA with Packet Error Checking (PEC) STOP 02661-060 SMBUS Alert Response 4. If more than one devices INT/INT output is low, the one with the lowest device address has priority, in accordance with typical SMBus specifications. ADT7316/ADT7317/ADT7318 LAYOUT CONSIDERATIONS Digital boards can be electrically noisy environments, and care must be taken to protect the analog inputs from noise, particularly when measuring the very small voltages from a remote diode sensor. Take the following precautions: • • Place the ADT7316/ADT7317/ADT7318 as close as possible to the remote sensing diode. Provided that the worst noise sources, such as clock generators, data/address buses, and CRTs are avoided, this distance can be 4 inches to 8 inches. Route the D+ and D− tracks close together, in parallel, with grounded guard tracks on each side. Provide a ground plane under the tracks if possible. Use wide tracks to minimize inductance and reduce noise pickup. A 10 mil track minimum width and spacing is recommended. GND Try to minimize the number of copper/solder joints, which can cause thermocouple effects. Where copper/ solder joints are used, make sure that they are in both the D+ and D− paths and at the same temperature. Thermocouple effects should not be a major problem as 1°C corresponds to about 240 μV, and thermocouple voltages are about 3 μV/°C of the temperature difference. Unless there are two thermocouples with a big temperature differential between them, thermocouple voltages should be much less than 200 mV. • Place 0.1 μF bypass and 2200 pF input filter capacitors close to the ADT7316/ADT7317/ADT7318. • If the distance to the remote sensor is more than 8 inches, the use of the twisted pair cable is recommended. This works for distances from 6 feet to 12 feet. • For really long distances (up to 100 feet), use shielded twisted pair, such as Belden #8451 microphone cable. Connect the twisted pair to D+ and D− and the shield to GND close to the ADT7316/ADT7317/ADT7318. Leave the remote end of the shield unconnected to avoid ground loops. • Because the measurement technique uses switched current sources, excessive cable and/or filter capacitance can affect the measurement. When using long cables, the filter capacitor may be reduced or removed. 10 MIL 10 MIL 10 MIL D+ 10 MIL 10 MIL D– 10 MIL GND 10 MIL 02661-045 • • Cable resistance can also introduce errors. Series resistance of 1 Ω introduces about 0.5°C error. Figure 61. Arrangement of Signal Tracks Rev. B | Page 41 of 44 ADT7316/ADT7317/ADT7318 OUTLINE DIMENSIONS 0.197 0.193 0.189 9 16 0.158 0.154 0.150 1 0.244 0.236 0.228 8 PIN 1 0.069 0.053 0.065 0.049 0.010 0.025 0.004 BSC COPLANARITY 0.004 0.012 0.008 SEATING PLANE 0.010 0.006 8° 0° 0.050 0.016 COMPLIANT TO JEDEC STANDARDS MO-137-AB Figure 62. 16-Lead Shrink Small Outline Package [QSOP] (RQ-16) Dimensions shown in inches ORDERING GUIDE Model ADT7318ARQ ADT7318ARQ-REEL ADT7318ARQ-REEL7 ADT7318ARQZ 1 ADT7318ARQZ-REEL1 ADT7318ARQZ-REEL71 ADT7317ARQ ADT7317ARQ-REEL ADT7317ARQ-REEL7 ADT7317ARQZ1 ADT7317ARQZ-REEL1 ADT7317ARQZ-REEL71 ADT7316ARQ ADT7316ARQ-REEL ADT7316ARQ-REEL7 ADT7316ARQZ1 ADT7316ARQZ-REEL1 ADT7316ARQZ-REEL71 EVAL-ADT7316EB 1 Temperature Range −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C −40°C to +120°C DAC Resolution 8-Bits 8-Bits 8-Bits 8-Bits 8-Bits 8-Bits 10-Bits 10-Bits 10-Bits 10-Bits 10-Bits 10-Bits 12-Bits 12-Bits 12-Bits 12-Bits 12-Bits 12-Bits Package Description 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP Evaluation Board Z = Pb-free part. Rev. B | Page 42 of 44 Package Option RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 RQ-16 Ordering Quantity 98 2,500 1,000 98 2,500 1,000 98 2,500 1,000 98 2,500 1,000 98 1,000 1,000 98 2,500 1,000 ADT7316/ADT7317/ADT7318 NOTES Rev. B | Page 43 of 44 ADT7316/ADT7317/ADT7318 NOTES ©2003–2007 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. C02661-0-1/07(B) Rev. B | Page 44 of 44