MIC384-2BMM Micrel Inc, MIC384-2BMM Datasheet

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... MIC384-0BM MIC384-0YM MIC384-1BM MIC384-1YM MIC384-2BM MIC384-2YM MIC384-3BM MIC384-3YM MIC384-0BMM MIC384-0YMM MIC384-1BMM MIC384-1YMM MIC384-2BMM MIC384-2YMM MIC384-3BMM MIC384-3YMM * The least-significant bit of the slave address is determined by the state of the A0 pin. Typical Application 3.3V 3 × 10k pull-ups FROM SERIAL BUS HOST 3-Channel SMBus Temperature Measurement System Micrel, Inc. • ...

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... Ground: Power and signal return for all IC functions. Analog Input: Connection to remote temperature sensor (diode junc- tion) Analog Input: Connection to remote temperature sensor (diode junc- tion) Digital Input: Slave address selection input. See Table 1. MIC384 Slave Address Settings. Analog Input: Power supply input to the IC. 2 Micrel ...

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... Min Typ 350 3 1 2.0 250 ±1 ±2 ±1 ≤ +85°C A ±2 50 100 224 7.5 14 2.0 10 ±0.01 Micrel Max Units 750 µA µA 10 µA 200 µs 2 ±2 °C ±3 °C ±3 °C ±5 ° 160 ms 400 µA µA 0 ±1 µA MIC384 ...

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... Testing is performed using a single unit of one of the transistors listed in Table 6. D Note 6. Current into this pin will result in self-heating of the MIC384. Sink current should be minimized for best accuracy. Note 7. Guaranteed by design over the operating temperature range. Not 100% production tested. ...

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... MIC384 Timing Diagram SDA Data In SDA Data Out September 2005 t 1 SCL Serial Interface Timing MIC384 Micrel ...

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... Each MIC384 will only respond to its own unique slave address, allowing up to eight MIC384’s to share a single bus. A match between the MIC384’s address and the address specified in the serial bit stream must be made to initiate communication. A0 should be tied directly to VDD or ground. See " ...

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... A new start bit must then be sent to the MIC384, followed by a repeat of the slave address with the R/W bit (LSB) set to the high (read) state. The data to be read from the part may then be clocked out ...

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... MIC384 MIC384 8 Micrel September 2005 ...

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... MIC384 September 2005 9 Micrel MIC384 ...

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... Table 3 shows examples of the data format used by the MIC384 for temperatures. A/D Converter Timing Whenever the MIC384 is not in its low power shutdown mode, the internal A/D converter (ADC) attempts to make continuous conversions unless interrupted by a bus transaction access- ing the MIC384. ...

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... MIC384 T September 2005 ° ° ° ° ° – ° – 2 ° – 4 ° – 5 ° Table 3. Digital Temperature Format Micrel MIC384 ...

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... Interrupt Generation Assuming the MIC384 is in interrupt mode and interrupts are enabled, there are seven different conditions that will cause the MIC384 to set one of the status bits, S0, S1, or MIC384 S2, in CONFIG and assert its /INT output. These conditions are listed in Table 5. When a temperature event occurs, the corresponding status bit will be set in CONFIG ...

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... MIC384 September 2005 > > > < < < ° Table 5. MIC384 Temperature Events Micrel / MIC384 ...

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... CONFIG Power-Up Value: 0000 0000 • not in shutdown mode • comparator mode • Fault_Queue depth = 1 • interrupts enabled. • no temperature events pending CONFIG Command Byte Value: 0000 0001 * Following the first Fault_Queue conversions, one or more of the status bits may be set. MIC384 ...

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... Each LSB represents one degree Centigrade. The values are two's complement format such that 0°C is reported 0000 0000 See "Temperature Data Format" for more details See "Temperature Data Format" for more details See "Temperature Data Format" for more details. b Micrel MIC384 ...

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... TEMP1 Power-Up Value: 0000 0000 TEMP1 Command Byte Value: 0001 0000 Remote Zone 1 Hysteresis Register T_HYST1 Power-Up Value: 0101 1100 T_HYST1 Command Byte Value: 0001 0010 Remote Zone 1 Temperature Setpoint Register T_SET1 Power-Up Value: 0110 0001 T_SET1 Command Byte Value: 0001 0011 MIC384 ...

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... Each LSB represents one degree Centigrade. The values are two's complement format such that 0°C is reported as h 0000 0000 See "Temperature Data Format" for more details See "Temperature Data Format" for more details See "Temperature Data Format" for more details. b Micrel MIC384 ...

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... Filter capacitor selection It is sometimes desirable to use a filter capacitor between the T1 and/or T2 pins and the GND pin of the MIC384. The use of these capacitors is recommended in environments with a lot of high frequency noise (such as digital switching noise long wires are used to attach to the remote di- odes ...

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... Layout Considerations The following guidelines should be kept in mind when design- ing and laying out circuits using the MIC384: 1. Place the MIC384 as close to the remote diodes as possible, while taking care to avoid severe noise sources such as high frequency power transformers, CRTs, memory and data busses, and the like ...

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... MIC384 3.3V 10k pull-ups FROM SERIAL BUS HOST Figure 7. V MIC384 100 0.1µF 4.7µF MIC384 DATA VDD CLK T1 / INT T2 GND A0 Decoupling for Very Noisy Supplies DD 20 Remote Diode 2200pF Remote Diode 2200pF September 2005 Micrel ...

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... MIC384 Package Information September 2005 8-Lead SOIC (M) 8-Lead MSOP (MM) 21 Micrel MIC384 ...

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... Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser's use or sale of Micrel Pr MIC384 + 1 (408) 474-1000 FAX WEB Micrel for any damages resulting from such use or sale ...