SMM465FR05

SMM465 4-Channel Active DC Output Controller, Monitor, Marginer and Sequencer FEATURES & APPLICATIONS • Extremely accurate (±0.1%) Active DC Output Control (ADOCTM) • Undervoltage Lockout function (UVLO) • ADOCTM Automatically adjusts supply output voltage level under all DC load conditions • Monitors, controls, sequences and margins up to 4 supplies from 0.3V to 5.5V with 1.25V Vref Wide Margin/ADOC range from 0.3V to VDD • Programmable Power-on/-off sequencing • Monitors internal temperature sensor • Operates from any intermediate bus supply from 8V to 15V and from 2.7V to 5.5V • Monitors 12V input and VDD • Monitors two general-purpose 10-bit ADC inputs • Programmable threshold limits (2 OV/2 UV) for each monitored input • Programmable RESET, HEALTHY and FAULT • 4k-bit general purpose nonvolatile memory • I2C 2-wire serial bus for programming configuration and monitoring status, including 10-bit ADC conversion results Applications • Monitor/Control Distributed and POL Supplies • Multi-voltage Processors, DSPs, ASICs used in Telecom, CompactPCI or server systems Preliminary Information1 (See Last Page) INTRODUCTION The SMM465 is an Active DC Output power supply Controller (ADOCTM) that monitors, margins and cascade sequences. The ADOC feature is unique and maintains extremely accurate settings of system supply voltages to within ±0.2% under full load. The device actively controls up to four DC/DC converters that use a Trim or Regulator VADJ/FB pin to adjust the output voltage. For system test, the part also controls margining of the supplies using I2C commands. It can margin supplies with either positive or negative control within a range of 0.3V to VDD depending on the specified range of the converter. The SMM465 also intelligently sequences or cascades the power supplies on and off in any order using enable outputs with programmable polarity. It can operate off any intermediate bus supply ranging from 8V to 15V or from 5.5V to as low as 2.7V. The part monitors four power supply channels as well as VDD, 12V input, two general-purpose analog inputs and an internal temperature sensor using a 10-bit ADC. The 10-bit ADC can measure the value on any one of the monitor channels and output the data via the I2C bus. A host system can communicate with the SMM465 status register, optionally control Power-on/off, margining and utilize 4K-bits of nonvolatile memory. SIMPLIFIED APPLICATIONS DRAWING 12VIN (+6V to +15V Range) 3.3VIN (+2.7V to +5.5V Range) 12VIN VDD CAPA TRIM_CAPA DC/DC Converter C VIN DC/DC Converter A Vout TRIM ON/OFF 2 of 4 DC-DC Converters shown 12V 3.3V SDA I2C BUS SCL A2 External or Internal TEMP SENSOR Environ mental SENSOR External or Internal REFERENCE 2.5VIN TRIMA PUPA AIN1 SMM465 AIN2 VREF_CNTL VREF_ADC HEALTHY VMA CAPB DC/DC Converter D VIN DC/DC Converter B Vout TRIM ON/OFF TRIM_CAPB µP/ ASIC 1.2VIN TRIMB PUPB RST MR VMB HEALTHY RESET READY Figure 1 – Applications Schematic using the SMM465 Controller to actively control the output levels of up to four DC/DC Converters while also providing power on/off, cascade sequencing and output margining. Note: This is an applications example only. Some pins, components and values are not shown. © SUMMIT Microelectronics, Inc. 2004 • 1717 Fox Drive • San Jose CA 95131 • Phone 408 436-9890 • FAX 408 436-9897 www.summitmicro.com 2085 1.1 05/27/04 1 SMM465 VDD (+2.7V to +5.5V) or 12VIN ( +8V to +15V) Preliminary Information 2.7V 2.5V 1.8V 1.5V RST# --- t1 --- Figure 2 – Example Power Supply Sequencing and System Start-up Initialization using the SMM465. Any order of supply sequencing can be applied using the SMM465. Power supply ordering, trimming and Active DC control allows supply cascade sequencing, automatic level adjustment, margin testing and reset control. GENERAL DESCRIPTION The SMM465 is a highly integrated and accurate power supply controller, monitor and sequencer. It has the ability to automatically control, monitor and cascade sequence up to four power supplies. Also, the SMM465 can monitor the VDD input, the 12V input, two general-purpose analog inputs and the internal temperature sensor. The SMM465 has four operating modes: Power-on sequencing mode, monitor mode, supply margining mode using Active DC Output Control (ADOCTM), and Power-off sequencing mode. Power-on sequencing can be initiated via the PWR_ON/OFF pin or I2C control. In this mode, the SMM465 will sequence the power supply channels on in any order by activating the PUP outputs and monitoring the respective converter voltages to ensure cascading of the supplies. Cascade sequencing is the ability to hold off the next sequenced supply until the first supply reaches a programmed threshold. A programmable sequence termination timer can be set to disable all channels if the Power-on sequence stalls. Once all supplies have sequenced on and the voltages are above the UV settings, the Active DC Control, if enabled, will bring the supply voltages to their nominal settings. During this mode, the HEALTHY output will remain inactive and the RST output will remain active. Once the Power-on sequencing mode is complete, the SMM465 enters monitor mode. In the monitor mode, the SMM465 starts the ADOC control of the supplies and adjusts the output voltage to the programmed setting under all load conditions, especially useful for supplies without sense lines. Typical converters have ±2% accuracy ratings for their output voltage, the Active DC Output Control feature of the SMM465 increases the accuracy to ±0.2% (using a ±0.1% external voltage reference). The part also enables the triggering of outputs by monitored fault conditions. The 10-bit ADC cycles through all 9 channels every 2ms and checks the conversions against the programmed threshold limits. The results can be used to trigger RST, HEALTHY and FAULT outputs as well as to trigger a Power-off or a Force Shutdown operation. While the SMM465 is in its monitoring mode, an I2C command to margin the supply voltages can bring the part into margining mode. In margining mode the SMM465 can margin four supply voltages in any combination of nominal, high and low voltage settings using the ADOC feature, all to within ±0.2% using a ±0.1% external reference. The margin high and low voltage settings can range from 0.3V to VDD around the converters’ nominal output voltage setting depending on the specified margin range of the DCDC converter. During this mode the HEALTHY output is always active and the RST output is always inactive regardless of the voltage threshold limit settings and triggers. Furthermore, the triggers for Power-off and Force Shutdown are temporarily disabled. The Power-off sequencing mode can only be entered while the SMM465 is in the monitoring mode. It can be initiated by either bringing the PWR_ON/OFF pin inactive, through I2C control or triggered by a channel exceeding its programmed thresholds. Once Poweroff is initiated, it will disable the Active DC Control and sequence the PUP outputs off in either the same or reverse order as Power-on sequencing and monitor the supply voltages to ensure cascading of the supplies as they turn off. The sequence termination timer can be programmed to immediately disable all channels if the Power-off sequencing stalls. The RST output will remain active throughout this mode while the HEALTHY output remains inactive. 2 Summit Microelectronics, Inc 2085 1.1 05/27/04 SMM465 Preliminary Information INTERNAL FUNCTIONAL BLOCK DIAGRAM 12VIN VDD VDD_CAP PWR_ON/OFF FS VREF_ADC AIN1 AIN2 VM A CAPA 3.6V or 5.5V Regulator Power Supply Arbitrator UVLO Control Cascade Sequence Control PUPA PUPB PUPC PUPD 10-Bit ADC Temperature Sensor VM D MR CAPD RST HEALTHY FAULT TRIM A TRIM_CAPA Output Control Active DC Control (ADOCTM) TRIM D TRIM_CAPD VREF_CNTL FILT_CAP Memory, Limit and Status Registers SDA I2C Interface SCL A2 GND Figure 3 – SMM465 Internal Functional Block Diagram. Summit Microelectronics, Inc 2085 1.1 05/27/04 3 SMM465 Preliminary Information PIN DESCRIPTIONS Pin Number 1 2 3 Pin Type DATA CLK IN Pin Name SDA SCL A2 Pin Description I2C Bi-directional data line I2C Clock line The address pin is biased either to VDD_CAP or GND. When communicating with the SMM465 over the 2-wire bus A2 provides a mechanism for assigning a unique bus address. Programmable active high/low input. When asserted the RST output will be go active. When de-asserted the RST output will go inactive immediately after a reset timeout period (tPRTO) if there are no RST trigger sources active. This timeout period makes it suitable to use a pushbutton for manual reset. Programmable active high/low input signals the start of the power sequencing. When asserted the part will sequence the supplies on and when de-asserted the part will sequence the supplies off. Note: The SMM465 does not monitor for faults during sequencing. The PWR_ON/OFF pin is overridden by the I2C power on/off command. To get the pin to work again requires the part be given an I2C 'Clear' command (see page 16, “RESTART OF POWER-ON CASCADE SEQUENCING”). Programmable active high/low input. Force shutdown is used to immediately turn off all converter enable signals (PUP outputs) when a fault is detected. Programmable active high/low open drain Fault output. Active when a programmed fault condition exists on AIN1, AIN2, or the internal temperature sensor. Programmable active high/low open drain Healthy output. Active when all programmed power supply inputs and monitored inputs are within OV and UV limits. Programmable active high/low open drain Reset output. Active when a programmed fault condition exists on any power supply inputs or monitored inputs or when MR is active. RST has a programmable timeout period with options for 0.64ms, 25ms, 100ms and 200ms. General purpose monitored analog input General purpose monitored analog input Ground Voltage reference input used for A/D conversion where: (4XVREF_ADC) = Full Scale (FS) for VMA-F and VDD (12XVREF_ADC) = FS for 12VIN (2XVREF_ADC) = FS for AIN1 and AIN2. VREF_ADC can be connected to VREF_CNTL in most applications. 4 IN MR 5 IN PWR_ON/OFF 6 7 IN OUT FS FAULT 8 OUT HEALTHY 9 OUT RST 10 11 12, 19, 24 IN IN GND AIN1 AIN2 GND 13 IN VREF_ADC Summit Microelectronics, Inc 2085 1.1 05/27/04 4 SMM465 Preliminary Information PIN DESCRIPTIONS (Cont.) Pin Number 14 15 41,36, 31,26 42,37, 32,27 43,38, 33,28 44,39, 34,29 45,40, 35,30 46 47 48 16, 17, 18, 20, 21, 22, 23, 25 Pin Type I/O CAP IN CAP OUT OUT CAP PWR PWR CAP NC Pin Name VREF_CNTL FILT_CAP VMX CAPX PUPX TRIMX TRIM_CAPX VDD 12VIN VDD_CAP No Connect Pin Description Voltage reference input used for DC output control and margining. VREF_CNTL can be programmed to output the internal 1.25V reference. External capacitor input used to filter VMX inputs Positive converter sense line, VMA through VMD External capacitor input used to filter the VMX inputs to the 10-bit ADC, CAPA through CAPD. This provides an RC filter where R = 25kΩ. Programmable active high/low open drain converter enable output, PUPA through PUPD Output voltage used to control the output of DC/DC converters, TRIMA through TRIMD External sample and hold capacitor input used to set the voltage on the TRIM pins, TRIM_CAPA through TRIM_CAPD Power supply of the part 12V power supply input internally regulated to either 3.6V or 5.5V External capacitor input used to filter the internal supply Leave open, do not connect. Summit Microelectronics, Inc 2085 1.1 05/27/04 5 SMM465 Preliminary Information PACKAGE AND PIN CONFIGURATION 48 LEAD TQFP TRIM_CAPA TRIM_CAPB VDD_CAP TRIMA TRIMB PUPB 38 48 47 46 45 44 43 42 41 40 39 SDA SCL A2 MR PWR_ON/OFF FS FAULT HEALTHY RST AIN1 AIN2 GND 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 37 36 35 34 33 32 31 30 29 28 27 26 25 CAPB 12VIN PUPA CAPA VMA VDD VMB TRIM_CAPC TRIMC PUPC CAPC VMC TRIM_CAPD TRIMD PUPD CAPD VMD NC VREF_ADC VREF_CNTL FILT_CAP GND GND NC NC NC NC NC NC NC Summit Microelectronics, Inc 2085 1.1 05/27/04 6 SMM465 Preliminary Information ABSOLUTE MAXIMUM RATINGS Temperature Under Bias....................... -55°C to 125°C Storage Temperature............................ -65°C to 150°C Terminal Voltage with Respect to GND: VDD Supply Voltage ......................... -0.3V to 6.0V 12VIN Supply Voltage ..................... -0.3V to 15.0V PUPA, through PUPD....................... -0.3V to 15.0V All Others ................................-0.3V to VDD + 0.7V Output Short Circuit Current ............................... 100mA Lead Solder Temperature (10 secs) .................... 300°C Junction Temperature.......................…….....…...150°C ESD Rating per JEDEC…………………....……..2000V Latch-Up testing per JEDEC………..…....……±100mA Note - The device is not guaranteed to function outside its operating rating. Stresses listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only and functional operation of the device at these or any other conditions outside those listed in the operational sections of the specification is not implied. Exposure to any absolute maximum rating for extended periods may affect device performance and reliability. Devices are ESD sensitive. Handling precautions are recommended. RECOMMENDED OPERATING CONDITIONS Temperature Range (Industrial)...........–40°C to +85°C (Commercial) ............–5°C to +70°C VDD Supply Voltage .................................. 2.7V to 5.5V 12VIN Supply Voltage (1) ........................ 8.0V to 14.0V VIN ............................................................ GND to VDD VOUT ...................................................... GND to 14.0V Package Thermal Resistance (θJA) 48 Lead TQFP……………………………….…80oC/W Moisture Classification Level 1 (MSL 1) per J-STD- 020 Note 1 – Range depends on internal regulator set to 3.6V or 5.5V, see 12VIN specification below. RELIABILITY CHARACTERISTICS Data Retention…………………………..…..100 Years Endurance…………………….……….100,000 Cycles DC OPERATING CHARACTERISTICS (Over recommended operating conditions, unless otherwise noted. All voltages are relative to GND.) Symbol Parameter Notes Min Typ Max VDD Supply Voltage 2.7 5.5 12VIN IDD I12VIN Supply Voltage Power Supply Current from VDD Power Supply Current from 12VIN Internally regulated to 5.5V Internally regulated to 3.6V Unit V V V mA mA 10 6 3 3 14 14 5 5 All TRIM pins floating, 12VIN floating All TRIM pins floating, VDD floating TRIM Sourcing Maximum Current TRIM Sinking Maximum Current Depends on Trim range of DC-DC Converter VDD = 2.7V VDD = 5.0V VDD = 2.7V VDD = 5.0V Internally regulated to 3.6V Internally regulated to 5.5V Internally regulated to 3.6V Internally regulated to 5.5V 2085 1.1 05/27/04 TRIM characteristics ITRIM TRIM output current through 100Ω to 1.0V Margin Control and ADOC Range Input High Voltage (FS, PWR_ON/OFF, MR#, SDA, SCL) Input Low Voltage (FS, PWR_ON/OFF, MR#, SDA, SCL) Input High Voltage (FS, PWR_ON/OFF, MR#, SDA, SCL) Input Low Voltage (FS, PWR_ON/OFF, MR#, SDA, SCL) 1.5 1.5 VREF_CNTL/4 mA mA VDD VDD VDD 0.1xVDD 0.3xVDD VDD VDD 0.1xVDD 0.3xVDD 7 V V V V V V V V V VTRIM All other input and output characteristics VIH VIL VIH VIL 0.9xVDD 0.7xVDD -0.1 -0.1 0.9xVDD 0.7xVDD -0.1 -0.1 Summit Microelectronics, Inc SMM465 Preliminary Information DC OPERATING CHARACTERISTICS (CONTINUED) (Over recommended operating conditions, unless otherwise noted. All voltages are relative to GND.) Symbol Parameter Notes Min Typ Max Programmable Open Drain Outputs (RST, HEALTHY, VOL ISINK = 1mA 0 0.4 FAULT, PUPx) IOL VSENSE VMonitor TSA TMonitor VREF VREF TC VREF ACC Ext VREF Output Low Current Positive Sense Voltage Monitor Threshold Step Size Internal Temperature Sensor Accuracy Temperature Threshold Step Size Internal 1.25VREF Output Voltage Internal VREF Temperature Coefficient Internal VREF Accuracy External VREF Voltage Range External VREF=1.25V, ±0.1%, Total PUPx ISINK < 3ma, VSENSE ≤ 3.5V External VREF=1.25V, ±0.1%, Total PUPx ISINK < 3ma, VSENSE ≥ 3.5V Internal VREF=1.25V, Total PUPx ISINK < 3ma VDD_CAP voltage at which the PUP, RST, HEALTHY and FAULT outputs are valid VDD_CAP Rising VDD_CAP Falling Note – Total ISINK from all PUPx pins should not exceed 3mA or ADOCACC specification will be affected Unit V mA V mV o o o 0 +0.3 5 -3 -5 1.24 0.25 1.25 1.0 VDD_CAP VM pin VM, AIN1/AIN2 pins Commercial Temp Range Industrial Temp Range Internal Temp Sensor –40°C to +85°C –5°C to +70°C +3 +5 1.26 +0.25 +0.15 +0.4 VDD_CAP C C C V -0.25 -0.15 -0.4 0.5 -0.2 % % % V % ±0.1 ±0.3 ±0.3 1 2.6 2.5 +0.2 ADOCACC ADOC/Margin Accuracy -0.5 -0.5 +0.5 +0.5 % % V V V VOUT_VALID UVLO Minimum Output Valid Voltage Under Voltage Lockout Threshold1 Note 1 - (100mV typ Hysteresis) Summit Microelectronics, Inc 2085 1.1 05/27/04 8 SMM465 Preliminary Information DC OPERATING CHARACTERISTICS (CONTINUED) (Over recommended operating conditions, unless otherwise noted. All voltages are relative to GND.) AIN1/AIN2 ADC characteristics Symbol N MC S/N DNL INL GAIN Offset ADC_TC IMADC IIVREF_ADC ICVREF_ADC IRVREF_ADC Parameter Resolution Missing Codes Signal-to-Noise Ratio Differential Non-Linearity Integral Non-Linearity Positive full scale gain error Offset Error Full Scale Temperature Coefficient Analog ADC Input Impedance VREF_ADC Input Current VREF_ADC Input Capacitance VREF_ADC Input Impedance Minimum resolution for which no missing codes are guaranteed Notes Min 10 10 Typ Max Unit Bits Bits Conversion rate = 500Hz Note 1 Note 1 Note 1 -1/2 -1 -0.5 -1 72 +1/2 +1 +0.5 +1 ±15 10 250 200 1 db LSB LSB % LSB PPM/oC MΩ nA pF kΩ Note 1 - The formula for the total ADC inaccuracy is: [((ADC read voltage) +/- INL)*(range of gain error)]+range of offset error Summit Microelectronics, Inc 2085 1.1 05/27/04 9 SMM465 Preliminary Information AC OPERATING CHARACTERISTICS Over recommended operating conditions, unless otherwise noted. All voltages are relative to GND. See Figure 5 and 6 Timing diagrams. Symbol tDPON Description Programmable Power-on delay from VMX out-of-fault to PUPX active Programmable Power-off delay from VMX off to PUPX inactive Programmable Reset Time-Out Period Conditions tDPON = 0.64ms tDPON = 12.5ms tDPON = 25ms tDPON = 50ms tDPOFF = 0.64ms tDPOFF = 12.5ms tDPOFF = 25ms tDPOFF = 50ms tPRTO = 0.64ms tPRTO = 25ms tPRTO = 100ms tPRTO = 200ms tSTT = OFF tSTT = 100ms tSTT = 200ms tSTT = 400ms Time for ADC conversion of all 11 channels Update period for Active DC Control of channels A–F Slow Margin, + 10% change in voltage with 0.1% ripple TRIM_CAP=1µF Fast Margin, + 10% change in voltage with 0.1% ripple TRIM_CAP=1µF Min -15 Typ tDPON Max +15 Unit % tDPOFF -15 tDPOFF +15 % tPRTO -15 tPRTO +15 % tSTT tADC tDC_CONTROL Programmable Sequence Termination Timer 10-bit ADC sampling period Active DC Control sampling period -15 tSTT 2 1.7 +15 % ms ms 850 ms TMARGIN Margin Time from Nominal 85 ms Summit Microelectronics, Inc 2085 1.1 05/27/04 10 SMM465 Preliminary Information I2C 2-WIRE SERIAL INTERFACE AC OPERATING CHARACTERISTICS – 100/400kHz Over recommended operating conditions, unless otherwise noted. All voltages are relative to GND. See Figure 4 Timing Diagram. Conditions 100kHz 400kHz Symbol Description Min Typ Max Min Typ Max fSCL tLOW tHIGH tBUF tSU:STA tHD:STA tSU:STO tAA tDH tR tF tSU:DAT tHD:DAT TI tWR_CONFIG tWR_EE SCL Clock Frequency Clock Low Period Clock High Period Bus Free Time Start Condition Setup Time Start Condition Hold Time Stop Condition Setup Time Clock Edge to Data Valid Data Output Hold Time SCL and SDA Rise Time SCL and SDA Fall Time Data In Setup Time Data In Hold Time Noise Filter SCL and SDA Write Cycle Time Config Write Cycle Time EE Noise suppression Configuration Registers Memory Array SCL low to valid SDA (cycle n) SCL low (cycle n+1) to SDA change Note 1/ Note 1/ Before New Transmission - Note 1/ Units KHz µs µs µs µs µs µs 0 4.7 4.0 4.7 4.7 4.0 4.7 0.2 0.2 100 0 1.3 0.6 1.3 0.6 0.6 0.6 400 3.5 0.2 0.2 0.9 µs µs 1000 300 250 0 100 10 5 150 0 100 1000 300 ns ns ns ns ns 10 5 ms ms Note: 1/ - Guaranteed by Design. TIMING DIAGRAMS t W R (For W rite O peration Only) t LOW tSU:DAT tSU:STO tBUF tR SCL tSU:SDA SDA ( IN) tF t HD:SDA tHIGH tHD:DAT tAA SDA ( OUT) t DH Figure 4 - Basic I2C Serial Interface Timing Summit Microelectronics, Inc 2085 1.1 05/27/04 11 SMM465 Preliminary Information TIMING DIAGRAMS (CONTINUED) 0 PUP A t DPONA 1 2 VM A PUP B t DPONB VM B t DPONC PUP C VM C PUP D t DPOND VM D Figure 5 - The SMM465 cascade sequencing the supplies on and then monitoring for fault conditions. 2 PUP A 1 0 t DPOFFA VM A PUP B t DPOFFB VM B PUP C t DPOFFC VM C PUP D t DPO FFD VM D Figure 6 - The SMM465 cascade sequencing the supplies off. Summit Microelectronics, Inc 2085 1.1 05/27/04 12 SMM465 Preliminary Information APPLICATIONS INFORMATION DEVICE OPERATION POWER SUPPLY The SMM465 can be powered by either a 12V input through the 12VIN pin or by a 3.3V or 5.0V input through the VDD pin. The 12VIN pin feeds an internal programmable regulator that internally generates either 5.5V or 3.6V. A voltage arbitration circuit allows the device to be powered by the highest voltage from either the regulator output or the VDD input. This voltage arbitration circuit continuously checks for these voltages to determine which will power the SMM465. The resultant internal power supply rail is connected to the VDD_CAP pin that allows both filtering and holdup of the internal power supply. To ensure that the input voltage is high enough for reliable operation, an under voltage lockout circuit holds the controlled supplies off until the UVLO thresholds are met. MODES OF OPERATION The SMM465 has four basic modes of operation (shown in Figures 5 through 8): Power-on cascade sequencing mode, ongoing operations-monitoring mode, supply margining mode and Power-off cascade sequencing mode. In addition, there are two features: ADOC and forced shutdown which can be used during monitoring and margining mode. A detailed description of each mode and feature follows. ACTIVE DC OUTPUT CONTROL (ADOCTM) The SMM465 can actively control the DC output voltage of bricks or DC/DC converters that have a trim pin during monitoring and margining mode. The converter may be an off-the shelf compact device, or may be a “roll your own” circuit on the application board. In either case, the SMM465 dramatically improves voltage accuracy (down to 0.2%) by implementing closed-loop ADOC active control. This utilizes the DC-DC’s “trim” pin as shown in Figure 12, or an equivalent output voltage feedback adjustment “VADJ” or “FB” node in a user’s custom circuit, Figure 13. Each of the TRIMX pins on the SMM465 is connected to the trim input pins on the power supply converters. A sense line from the channel’s point-ofload connects to the corresponding VM input. The ADOC function cycles through all four channels (A-D) every 1.7ms making slight adjustments to the voltage on the associated TRIMX output pins based on the voltage inputs on the VMX pins. These voltage adjustments allow the SMM465 to control the output voltage of power supply converters to within ±0.2% when using a ±0.1% external voltage reference. Figure 7 - Waveform shows four SMM465 channels exhibiting Sequence-on to Nominal voltage, Margin High or Low, Nominal voltage and then sequence-off Ch 1 = 2.5V DC-DC converter output (Yellow trace) Ch 2 = 1.8V DC-DC converter output (Blue trace) Ch 3 = 1.5V DC-DC converter output (Purple trace) Ch 4 = 1.2V DC-DC converter output (Green trace Figure 8 - Waveform shows two SMM465 channels Sequencing-on to Nominal voltage, Margin High and Low, and then sequence-off. Channel 3 and 4 shows the RST and HEALTHY signals. Ch 1 = 2.5V DC-DC converter output (Yellow trace) Ch 2 = 1.5V DC-DC converter output (Blue trace) Ch 3 = RST signal output (Purple trace) Ch 4 = HEALTHY signal output (Green trace Summit Microelectronics, Inc 2085 1.1 05/27/04 13 SMM465 Preliminary Information APPLICATIONS INFORMATION (CONTINUED) A pulse of current, either sourced or sunk for 5µs every 1.7ms, to the capacitors connected to the TRIM_CAPX pins adjusts the voltage output on the TRIMX pins. The voltages on the TRIM_CAPX pins are buffered and applied to the TRIMX pins. The voltage adjustments on the TRIMX pins cause a slight ripple of less than 1mV on the power supply voltages. The amplitude of this ripple is a function of the TRIM_CAP capacitor and the trim gain of the converter. Application Note 37 details the calculation of the TRIM_CAP capacitor to achieve a desired minimum ripple. Each channel can be programmed to either enable or disable the Active DC Control function. When disabled or not active, the TRIMX pins on the SMM465 are high impedance inputs. If disabled and not used, they can be connected to ground. The voltages on the TRIMX pins are buffered and applied to the TRIM_CAPX pins charging the capacitors. This allows a smooth transition from the converter powering up to its nominal voltage; to the SMM465 controlling that voltage, and to the Active DC Control nominal setting. The pulse of current can be increased to a 10X pulse of current until the power supply voltages are at their nominal settings by selecting the programmable Speed-Up Convergence option. As the name implies, this option decreases the time required to bring a supply voltage from the converter’s nominal output voltage to the Active DC Control nominal voltage setting. POWER-ON CASCADE SEQUENCING The SMM465 can be programmed to sequence up to four power supplies in any order. Each of these four channels (A-D) has an associated open drain PUP output that, when connected to a converter’s enable pin, controls the turn-on of the converter. The channels are assigned sequence positions to determine the order of the sequence. Any channel can also be programmed to not take part in the sequencing in applications with fewer than four supplies. The polarity of each of the PUPX outputs is programmable for use with various types of converters. Power-on sequencing can be initiated by the PWR_ON/OFF pin or via I2C control. The polarity of the PWR_ON/OFF pin is programmable. If hard wired in its active state the SMM465 will automatically initiate the Power-on sequence. Otherwise, toggling the PWR_ON/OFF pin to its active state will initiate the Power-on sequence. To enable software control of the sequencing feature, the SMM465 offers an I2C command to initiate Power-on sequencing while the PWR_ON/OFF pin is in its inactive state. The SMM465 can be programmed to wait until either or both VDD and 12VIN inputs are within their respective voltage threshold limits before Power-on sequencing is allowed to begin. This ensures that the converters have their full supply voltage before they are enabled. Once Power-on sequencing begins, the SMM465 will wait a Power-on delay time (tDPON) for any channel in the first sequence position (0) and then activate the PUPX outputs for those channels. The Power-on delay times are individually programmable for each channel. The SMM465 will then wait until all VMX inputs of the channels assigned to the first sequence position (0) are above their programmed UV1 thresholds which is called cascade sequencing. At this point, the SMM465 will enter the second sequence position (1) and begin to timeout the Power-on delay times for the associated channels. This process continues until all of channels in the sequence have turned on and are above their UV1 threshold. The status registers indicates that all sequenced power supply channels have turned on. Once these channels are above their UV1 thresholds, the SMM465 will begin the Active DC Control of the enabled channels. The Power-on sequencing mode ends when the Active DC Controlled channels are at their nominal voltage setting. The “Ready” bit in the status registers signifies that the voltages are at their set points. The programmable sequence termination timer can be used to protect against a stalled Power-on sequence. This timer resets itself at the beginning of each sequence position. All channels in the sequence position must go above their UV1 threshold before the sequence termination timer times out (tSTT) or the sequence will terminate and all PUPX outputs will be switched to their inactive state. The status registers contain bits that indicate the sequence has been terminated and in which sequence position the timer timed out. This timer has four settings of OFF, 100ms, 200ms and 400ms. Summit Microelectronics, Inc 2085 1.1 05/27/04 14 SMM465 Preliminary Information APPLICATIONS INFORMATION (CONTINUED) While the SMM465 is in the Power-on sequencing mode the RST output is held active and the HEALTHY output is held inactive regardless of trigger sources (Figure 8). The Power-off and Force Shutdown trigger options are also disabled while in this mode. Furthermore, the SMM465 will not respond to activity on the PWR_ON/OFF pin or to a Power-off I2C command during Power-on sequencing mode. ONGOING OPERATIONS-MONITORING MODE During ongoing operations mode, the part can (1) monitor (2) actively control via ADOC, and (3) use force shutdown if necessary. Once the Power-on sequence is complete and before a Power-off sequence has been initiated, the SMM465 continues to monitor all VMX inputs, the VDD and 12VIN inputs, and two temperature sensor inputs with a 10-bit ADC. Each of these inputs is sampled and converted by the ADC every 2ms. The ADC input has a range of 0V to four times the voltage on VREF_ADC for inputs VMA-D and the VDD input. The range is extended to 12 times VREF_ADC for the 12VIN input and is reduced to two times VREF_ADC for the AIN1 and AIN2 inputs. The SMM465 monitors internal temperature using the 10-bit ADC and the automonitor function. Two under temperature and two over temperature thresholds can be set, each with its own programmable trigger options and consecutive conversion before trigger counter. Resolution is 0.25 C per bit scaled over the range of -128 C to 127.75 C. The temperature value can be acquired over the I2C bus as a 10-bit signed two's complement value. The SMM465 compares each resulting ADC conversion with two programmable 10-bit undervoltage limits (UV1, UV2) and two programmable 10bit over-voltage limits (OV1, OV2) for the corresponding input. A consecutive conversion counter is used to provide filtering of the ADC inputs. Each limit can be programmed to require 1, 2, 4 or 6 consecutive out-of-limit conversions before it is said to be in fault. One in-limit conversion will remove the fault from the threshold limit. This provides digital filtering of the monitored inputs. The ADC inputs VMA-D can use additional filtering by connecting a capacitor from the corresponding CAPX pins to ground to form an analog RC filter (R=25kΩ). The input is considered to be in a fault condition if any of its limit thresholds are in fault. Setting an OV threshold limit to full-scale (3FFHEX), or setting an UV threshold limit to 000HEX ensures that the limit can never be in fault. The status registers provide the real-time status of all monitored inputs. The voltage threshold limits for inputs VMA-F, VDD and 12VIN can be programmed to trigger the RST and HEALTHY outputs as well as a Force Shutdown and Power-off operation when exceeded. The threshold limits for the internal temperature sensor and the AIN1 and AIN2 inputs can be programmed to trigger the RST, HEALTHY, and FAULT outputs. The HEALTHY and FAULT outputs of the SMM465 are active as long as the triggering limit remains in a fault condition. The RST output also remains active as long as the triggering limit remains in a fault condition; however, once the trigger source goes away the RST will remain active for a reset timeout period (tPRTO). TEMPERATURE SENSOR ACCURACY The internal temperature sensor accuracy is ±5oC from -40 to +90oC. The sensor measures the temperature of the SMM465 die and the ambient temperature. If VDD is at 5V, the die temperature is +2oC and at 12V, it is +4oC. In order to calculate this difference in specific applications measure the Vdd or 12VIN supply current and calculate the power dissipated and multiply by 80oC/W. For instance, 5V and 5mA is 25mW, which creates a 2oC offset. MARGINING The SMM465 has two additional Active DC Output Control voltage settings for channels A-D, margin high and margin low. The margin high and margin low voltage settings can range from 0.3V to VDD of the converters’ nominal output voltage depending on the specified margin range of the DC-DC converter. These settings are stored in the configuration registers and are loaded into the Active DC Control voltage setting by margin commands issued via the I2C bus. The channel must be enabled for Active DC Control in order to enable margining. The margin command registers contain two bits for each channel that decode the commands to margin high, margin low, or control to the nominal setting. Therefore, any combination of margin high, margin low, and nominal control is allowed in the margining mode. Once the SMM465 receives the command to margin the supply voltages, it begins adjusting the supply voltages to move toward the desired setting. When all channels are at their voltage setting, a bit is set in the margin status registers. Summit Microelectronics, Inc 2085 1.1 05/27/04 15 SMM465 Preliminary Information APPLICATIONS INFORMATION (CONTINUED) Note: Configuration writes or reads of registers 00HEX to 0FHEX should not be performed while the SMM465 is margining. POWER-OFF CASCADE SEQUENCING The SMM465 can be programmed to perform Poweroff sequencing in either the same order or reverse order of Power-on cascade sequencing. Power-off cascade sequencing can be initiated by the PWR_ON/OFF pin, via I2C control or triggered by a fault condition on any of the monitored inputs. Toggling the PWR_ON/OFF pin to its inactive state will initiate the Power-off sequence. To enable software control of the Power-off sequencing feature, the SMM465 offers an I2C command to initiate Power-off sequencing regardless of the state of the PWR_ON/OFF pin. Furthermore, Power-off sequencing can be initiated by a fault condition on a monitored input. Once Power-off sequencing begins, the SMM465 will wait a Power-off delay time (tDPOFF) for any channel in the last sequence position (reverse order) and then deactivate the PUP outputs for those channels. The Power-off delay times are individually programmable for each channel. The SMM465 will then wait until all VMX inputs of the channels assigned to that sequence position are below the programmed OFF thresholds. At this point, the SMM465 will decrement to the next sequence position and begin to timeout the Power-off delay times for the associated channels. This process continues until all of channels in the sequence have turned off and are below their OFF thresholds. The status register reveals that all sequenced channels have turned off. The Power-off sequencing mode ends when all sequenced supplies are below their OFF thresholds. The programmable sequence termination timer can be used to protect against a stalled Power-off sequence. This timer resets itself at the beginning of each sequence position. All channels in the sequence position must go below their OFF threshold before the sequence termination timer times out (tSTT) or the sequence will terminate and all PUP outputs will be switched to their inactive state. This timer has four settings of OFF, 100ms, 200ms and 400ms. The sequence termination timer can be disabled separately for Power-off sequencing. While the SMM465 is in the Power-off sequencing mode the RST output is held active and the HEALTHY output is held inactive regardless of trigger sources (Figure 8). The Force Shutdown trigger option is also disabled while in this mode. Furthermore, the SMM465 will not respond to activity on the PWR_ON/OFF pin or to a Power-on I2C command during Power-off sequencing mode. FORCE SHUTDOWN The Force Shutdown operation brings all PUPX outputs to their inactive state. This operation is used for an emergency shutdown when there is not enough time to sequence the supplies off. The Force Shutdown operation shuts off all sequenced channels and waits for the supply voltages to drop below their respective OFF thresholds. A Force Shutdown operation can be initiated by any one of four events. The first two methods for initiating a Force Shutdown are always enabled. Simply taking the FS pin to its active state will initiate a Force Shutdown operation and maintain it until the pin is brought to its inactive state. An I2C Force Shutdown command allows the Force Shutdown operation to be initiated via software control. This I2C Force Shutdown command sets a volatile register bit that triggers a Force Shutdown. This bit is cleared after all sequenced channels have dropped below their OFF voltage threshold. During Power-on and Power-off sequencing, the sequence termination timer can initiate a Force Shutdown operation. As described in the previous sections, the sequence termination timer triggers a Force Shutdown operation if it times out before the power supply voltages surpass their voltage thresholds. This Force Shutdown will remain active until all sequenced power supply channels have dropped below their OFF voltage threshold. While the SMM465 is in ongoing operations-monitor mode, a programmed fault condition on any power supply channel or on the 12VIN or VDD inputs can trigger a Force Shutdown. A Force Shutdown resulting from this will remain active until all sequenced power supply channels have dropped below their OFF voltage threshold. Summit Microelectronics, Inc 2085 1.1 05/27/04 16 SMM465 Preliminary Information APPLICATIONS INFORMATION (CONTINUED) SMM465 Brownout Recovery/Handling During a power ‘brown-out’ (Figure 9) the SMM465 can default to a power-off state, thus requiring toggling of the PWR_ON/OFF pin to enable the device to perform a power-on sequence. For applications using I2C control of the power-on/power-off function, the same result may be effected by, upon recovery of power, issuing a software (I2C) ‘Power-Off’ command -48V Supply 0V followed by a ‘Power-On’ command and ending with a ‘Clear’ command. If the PWR_ON/OFF pin is in the asserted state, the SMM465 will initiate a power-on sequence once all input conditions are met. Otherwise the PWR_ON/OFF pin may require toggling if, upon recovery from the ‘brownout’, it is in the de-asserted state. -48V Power Brown-Out SMM465 Supplies SMM465 Hold-Up Time +12VIN VDD_CAP Figure 9 - Power Brown-Out with Resulting Loss of SMM465 Supply Voltages Summit Microelectronics, Inc 2085 1.1 05/27/04 17 SMM465 Preliminary Information APPLICATIONS INFORMATION (CONTINUED) RESTART OF POWER-ON CASCADE SEQUENCING Once a Force Shutdown or Power-off operation has completed, the SMM465 can restart the Power-on cascade sequencing. The device can be programmed to automatically restart after a Force Shutdown provided the PWR_ON/OFF pin remains in the active state or the I2C Power-on command remains in the command register. If this option is not selected, the SMM465 requires toggling of the PWR_ON/OFF pin or toggling of the I2C commands by issuing a Power-off command and then reissuing the Power-on command in order to restart Power-on sequencing. In either case, assertion of the FS pin will prevent the SMM465 from restarting Power-on sequencing. In addition, the device can be programmed to check that VDD and the 12VIN are within their programmed voltage thresholds before restarting Power-on sequencing. In cases where brownout conditions (Figure 10) or loss of power are used to cause a sequence off of the supplies or a Force Shutdown, it is best to toggle the PWR_ON/OFF pin or use the I2C Power commands VDD_CAP 3.6V, 5.5V 2.6V 2.5V after the brownout condition is over or if the supplies do not fully discharge before initiating a Power-on sequence. Recommended Use of the PWR_ON/OFF pin: The PWR_ON/OFF pin is edge-triggered to lock out false or nuisance signals during both the power-on and power-off sequences. If during a system powerdown, whether deliberate or due to a failed power system, the VDD_CAP voltage falls below 2.5V, the SMM465 internal UVLO (UnderVoltage LockOut) circuit resets all internal logic. Once power has recovered above 2.6V the SMM465 will restart assuming the PWR_ON/OFF pin is in the asserted state or an I2C power command is issued. The SMM465 can be used with the PWR_ON/OFF pin either toggled by a logic level, controlled by a software command or tied either high or low as described in the data sheet. UVLO (Internal) Figure 10 - Timing Sequence recovering from a VDD_CAP Power ‘Brown-Out’ Summit Microelectronics, Inc 2085 1.1 05/27/04 18 SMM465 Preliminary Information APPLICATIONS INFORMATION (CONTINUED) Figure 11 – SMM465 Distributed power applications schematic. The accuracy of the external reference (U10) sets the accuracy of the ADOC function. Total accuracy with a ±0.1% external reference is ±0.2%. Summit Microelectronics, Inc 2085 1.1 05/27/04 19 SMM465 Preliminary Information APPLICATIONS INFORMATION (CONTINUED) 12V 12V VREG_IN PUPB TRIMB C8 Rtrim 1.6K SS1 FB1 R7 SDA I2C BUS SCL CS VMB+ R9 VSW1 FB1S SMM465 Not all components Shown For interface purposes only Part designators are from the International Rectifier iP1202 Demo board . PUPA TRIMA C7 Rtrim 3.3K VOUT1 1.5V SS2 FB2 R8 VIN R10 VMA+ IR iP1202 VSW2 FB2S VOUT2 2.5V Figure 12 – The SMM465 can be used to sequence and control discrete DC switching regulators. The ADOC function sets the output voltage of the IR iP1202 Regulator through the FBX feedback pins. Accuracy is improved even under full load, essentially acting as a “SENSE” pin. The sequence function is applied through the iP1202 SSX soft start pins. Figure 13 – Ch1 is set to 2.5V and Ch2 is set to 1.5V on the ip1202 board. Ch1 is set to sequence on first followed by Ch2 after 50ms. Then Ch1 is margined high while Ch2 is margined low. Ch2 is then sequenced off followed by Ch1 after 50ms. Figure 14 – This is the same sequencing-on function but with a shorter delay between channels, the HEALTHY and RESET flags are also shown. Summit Microelectronics, Inc 2085 1.1 05/27/04 20 SMM465 Preliminary Information DEVELOPMENT HARDWARE & SOFTWARE The end user can obtain the Summit SMX3200 programming system for device prototype development. The SMX3200 system consists of a programming Dongle, cable and WindowsTM GUI software. It can be ordered on the website or from a local representative. The latest revisions of all software and an application brief describing the SMX3200 is available from the website (www.summitmicro.com). The SMX3200 programming Dongle/cable directly between a PC’s parallel port and application. The device is then configured via an intuitive graphical user interface drop-down menus. interfaces the target on-screen employing The Windows GUI software will generate the data and send it in I2C serial bus format so that it can be directly downloaded to the SMM465 via the programming Dongle and cable. An example of the connection interface is shown in Figure 15. When design prototyping is complete, the software can generate a HEX data file that should be transmitted to Summit for approval. Summit will then assign a unique customer ID to the HEX code and program production devices before the final electrical test operations. This will ensure proper device operation in the end application. D1 1N4148 VDD_CAP Top view of straight 0.1" x 0.1 closed-side connector. SMX3200 interface cable connector. Pin 10, Reserved Pin 8, Reserved Pin 6, MR# Pin 4, SDA Pin 2, SCL Pin 9, 5V Pin 7, 10V Pin 5, Reserved Pin 3, GND Pin 1, GND SMM465 MR SDA SCL 10 8 6 4 2 9 7 5 3 1 0.1 F GND Figure 15 – SMX3200 Programmer I2C serial bus connections to program the SMM465. Note that the MR pin does not need to be connected to pin 6 for programming purposes. Summit Microelectronics, Inc 2085 1.1 05/27/04 21 SMM465 Preliminary Information I2C PROGRAMMING INFORMATION SERIAL INTERFACE Access to the configuration registers, general-purpose memory and command and status registers is carried out over an industry standard 2-wire serial interface (I2C). SDA is a bi-directional data line and SCL is a clock input. Data is clocked in on the rising edge of SCL and clocked out on the falling edge of SCL. All data transfers begin with the MSB. During data transfers SDA must remain stable while SCL is high. Data is transferred in 8-bit packets with an intervening clock period in which an Acknowledge is provided by the device receiving data. The SCL high period (tHIGH) is used for generating Start and Stop conditions that precede and end most transactions on the serial bus. A high-to-low transition of SDA while SCL is high is considered a Start condition while a low-to-high transition of SDA while SCL is high is considered a Stop condition. The interface protocol allows operation of multiple devices and types of devices on a single bus through unique device addressing. The address byte is comprised of a 4-bit device type identifier (slave address) and a 3-bit bus address. The remaining bit indicates either a read or a write operation. Refer to Table 1 for a description of the address bytes used by the SMM465. The device type identifier for the memory array is generally set to 1010BIN following the industry standard for a typical nonvolatile memory. There is an option to change the identifier to 1011BIN allowing it to be used on a bus that may be occupied by other memory devices. The configuration registers are grouped with the memory array and thus use 1010BIN or 1011BIN as the device type identifier. The command and status registers as well as the 10-bit ADC are accessible with the separate device type identifier of 1001BIN. The bus address bits A[1:0] are programmed into the configuration registers. Bus address bit A[2] can be programmed as either 0 or biased by the A2 pin. The bus address accessed in the address byte of the serial data stream must match the setting in the SMM465 and on the A2 pin. Any access to the SMM465 on the I2C bus will temporarily halt the monitoring function. This does not affect the ADOC function, which will continue functioning and control the DC outputs. This is true not only during the monitor mode, but also during Power-on and Power-off sequencing when the device is monitoring the channels to determine if they have turned on or turned off. The SMM465 halts the monitor function from when it acknowledges the address byte until a valid stop is received. WRITE Writing to the memory or a configuration register is illustrated in Figures 16, 17, 19, 21 and 22. A Start condition followed by the address byte is provided by the host; the SMM465 responds with an Acknowledge; the host then responds by sending the memory address pointer or configuration register address pointer; the SMM465 responds with an acknowledge; the host then clocks in on byte of data. For memory and configuration register writes, up to 15 additional bytes of data can be clocked in by the host to write to consecutive addresses within the same page. After the last byte is clocked in and the host receives an Acknowledge, a Stop condition must be issued to initiate the nonvolatile write operation. READ The address pointer for the configuration registers, memory, command and status registers and ADC registers must be set before data can be read from the SMM465. This is accomplished by a issuing a dummy write command, which is simply a write command that is not followed by a Stop condition. The dummy write command sets the address from which data is read. After the dummy write command is issued, a Start command followed by the address byte is sent from the host. The host then waits for an Acknowledge and then begins clocking data out of the slave device. The first byte read is data from the address pointer set during the dummy write command. Additional bytes can be clocked out of consecutive addresses with the host providing an Acknowledge after each byte. After the data is read from the desired registers, the read operation is terminated by the host holding SDA high during the Acknowledge clock cycle and then issuing a Stop condition. Refer to Figures 18, 20 and 23 for an illustration of the read sequence. Summit Microelectronics, Inc 2085 1.1 05/27/04 22 SMM465 Preliminary Information I2C PROGRAMMING INFORMATION (CONTINUED) WRITE PROTECTION The SMM465 powers up into a write protected mode. Writing a code to the volatile write protection register can disable the write protection. The write protection register is located at address 87HEX of slave address 1001BIN. Writing 0101BIN to bits [7:4] of the write protection register allow writes to the general-purpose memory while writing 0101BIN to bits [3:0] allow writes to the configuration registers. The write protection can reenable by writing other codes (not 0101BIN) to the write protection register. Writing to the write protection register is shown in Figure 16. CONFIGURATION REGISTERS The majority of the configuration registers are grouped with the general-purpose memory located at either slave address 1010BIN or 1011BIN. The bus address bits, A[1:0], used to differentiate the general-purpose memory from the configuration registers are set to 11BIN. Bus address bit A[2] can be programmed as either 0 or biased by the A2 pin. Two additional configuration registers are located at addresses 83HEX and 84HEX of slave address 1001BIN. Writing and reading the configuration registers is shown in Figures 17, 18, 19, 20 and 21 Note: Configuration writes or reads of registers 00HEX to 0FHEX should not be performed while the SMM465 is margining. GENERAL-PURPOSE MEMORY The 4k-bit general-purpose memory is located at either slave address 1010BIN or 1011BIN. The bus address bits, A[1:0], used to differentiate the generalpurpose memory from the configuration registers are set to 00BIN for the first 2k-bits and 01BIN for the second 2k-bits. Bus address bit A[2] can be programmed as either 0 or biased by the A2 pin. Slave Address 1001BIN Bus Address A2 A1 A0 The word address must be set each time the memory is accessed. Memory writes and reads are shown in Figures 22, 23 and 24. COMMAND AND STATUS REGISTERS The command and status registers are located at slave address 1001BIN. Writes and reads of the command and status registers are shown in Figures 25 and 26. ADC CONVERSIONS An ADC conversion on any monitored channel can be performed and read over the I2C bus using the ADC read command. The ADC read command, shown in Figure 27, starts with a dummy write to the 1001BIN slave address. Bits [6:3] of the word address byte are used to address the desired monitored input. Once the device acknowledges the channel address, it begins the ADC conversion of the addressed input. This conversion requires 70µs to complete. During this conversion time, acknowledge polling can be used. The SMM465 will not acknowledge the address bytes until the conversion is complete. When the conversion has completed, the SMM465 will acknowledge the address byte and return the 10-bit conversion along with a 4-bit channel address echo. GRAPHICAL USER INTERFACE (GUI) Device configuration utilizing the Windows based SMM465 graphical user interface (GUI) is highly recommended. The software is available from the Summit website (www.summitmicro.com). Using the GUI in conjunction with this datasheet and Application Note 33, simplifies the process of device prototyping and the interaction of the various functional blocks. A programming Dongle (SMX3200) is available from Summit to communicate with the SMM465. The Dongle connects directly to the parallel port of a PC and programs the device through a cable using the I2C bus protocol. Register Type Write Protection Register, Command and Status Registers, Two Configuration Registers, ADC Conversion Readout 1st 2-k Bits of General-Purpose Memory 2nd 2-k Bits of General-Purpose Memory Configuration Registers 1010BIN or 1011BIN A2 0 0 A2 0 1 A2 1 1 Table 1 - Address bytes used by the SMM465. Summit Microelectronics, Inc 2085 1.1 05/27/04 23 SMM465 Preliminary Information I2C PROGRAMMING INFORMATION (CONTINUED) M aster S T A R T 1 0 0 1 Bus Address A 2 A 1 A 0 Configuration Register Address = 87 HEX Data = 55 HEX S T O P 1 0 1 A C K W A C K 1 0 0 0 0 1 1 1 A C K 0 1 0 1 0 Slave 8 H EX W rite Protection Register Address 7 HEX 5 HEX U nlocks General Purpose EE 5 HEX U nlocks Configuration Registers Figure 16 – Write Protection Register Write S T A R T 1 Slave 0 1 S A 0 S T O P D 2 D 1 D 0 A C K Master Bus Address A 2 C 7 A C K C 6 Configuration Register Address W C 5 C 4 C 3 C 2 C 1 C 0 A C K D 7 D 6 D 5 Data D 4 D 3 1 1 Figure17 – Configuration Register Byte Write S T A R T 1 Slave 0 1 S A 0 Master Bus Address A 2 C 7 A C K C 6 Configuration Register Address C 5 C 4 C 3 C 2 C 1 C 0 A C K D 7 D 6 D 5 Data (1) D 4 D 3 D 2 D 1 D 0 A C K 1 1 W Master D 7 Slave D 6 D 5 Data (2) D 4 D 3 D 2 D 1 D 0 A C K D 7 D 6 D 5 D 2 D 1 D 0 A C K D 7 D 6 D 5 Data (16) D 4 D 3 D 2 D 1 D 0 A C K S T O P Figure 18 – Configuration Register Page Write Summit Microelectronics, Inc 2085 1.1 05/27/04 24 SMM465 Preliminary Information I2C PROGRAMMING INFORMATION (CONTINUED) S T A R T 1 Slave 0 1 S A 0 S T A R T C 1 C 0 A C K 1 0 1 S A 0 Master Bus Address A 2 C 7 A C K C 6 Configuration Register Address W C 5 C 4 C 3 C 2 Bus Address A 2 1 1 1 1 R A C K Master D 7 Slave D 6 D 5 Data (1) D 4 D 3 D 2 D 1 D 0 A C K D 7 D 6 D 5 D 2 D 1 D 0 A C K D 7 D 6 D 5 Data (n) D 4 D 3 D 2 D 1 D 0 N A C K S T O P Figure 19 - Configuration Register Read S T A R T 1 Slave 0 0 1 Master Bus Address A 2 A 1 A 0 C 7 A C K C 6 Configuration Register Address W C 5 C 4 C 3 C 2 C 1 C 0 A C K D 7 D 6 D 5 Data D 4 D 3 D 2 D 1 D 0 A C K S T O P Figure 20 - Configuration Register with Slave Address 1001BIN Write S T A R T 1 Slave 0 0 1 S T A R T C 1 C 0 A C K 1 0 0 1 Master Bus Address A 2 A 1 A 0 C 7 A C K C 6 Configuration Register Address W C 5 C 4 C 3 C 2 Bus Address A 2 A 1 A 0 R A C K Master D 7 Slave D 6 D 5 Data (1) D 4 D 3 D 2 D 1 D 0 A C K D 7 D 6 D 5 D 2 D 1 D 0 A C K D 7 D 6 D 5 Data (n) D 4 D 3 D 2 D 1 D 0 N A C K S T O P Figure 21 - Configuration Register with Slave Address 1001BIN Read Summit Microelectronics, Inc 2085 1.1 05/27/04 25 SMM465 Preliminary Information I2C PROGRAMMING INFORMATION (CONTINUED) S T A R T 1 Slave 0 1 S A 0 S T O P D 2 D 1 D 0 A C K Master Bus Address A 2 0 / 1 C 7 A C K C 6 Memory Address C 5 C 4 C 3 C 2 C 1 C 0 A C K D 7 D 6 D 5 Data D 4 D 3 0 W Figure 22 – General Purpose Memory Byte Write S T A R T 1 Slave 0 1 S A 0 Master Bus Address A 2 0 / 1 C 7 A C K C 6 Memory Address C 5 C 4 C 3 C 2 C 1 C 0 A C K D 7 D 6 D 5 Data (1) D 4 D 3 D 2 D 1 D 0 A C K 0 W Master D 7 Slave D 6 D 5 Data (2) D 4 D 3 D 2 D 1 D 0 A C K D 7 D 6 D 5 D 2 D 1 D 0 A C K D 7 D 6 D 5 Data (16) D 4 D 3 D 2 D 1 D 0 A C K S T O P Figure 23 - General Purpose Memory Page Write S T A R T 1 Slave 0 1 S A 0 S T A R T C 1 C 0 A C K 1 0 1 S A 0 Master Bus Address A 2 0 / 1 C 7 A C K C 6 Memory Address C 5 C 4 C 3 C 2 Bus Address A 2 0 / 1 0 W 0 R A C K Master D 7 Slave D 6 D 5 Data (1) D 4 D 3 D 2 D 1 D 0 A C K D 7 D 6 D 5 D 2 D 1 D 0 A C K D 7 D 6 D 5 Data (n) D 4 D 3 D 2 D 1 D 0 N A C K S T O P Figure 24 - General Purpose Memory Read Summit Microelectronics, Inc 2085 1.1 05/27/04 26 SMM465 Preliminary Information I2C PROGRAMMING INFORMATION (CONTINUED) S T A R T 1 Slave 0 0 1 S T O P D 2 D 1 D 0 A C K Master Bus Address A 2 A 1 A 0 C 7 A C K C 6 Command and Status Register Address W C 5 C 4 C 3 C 2 C 1 C 0 A C K D 7 D 6 D 5 Data D 4 D 3 Figure 25 – Command and Status Register Write S T A R T 1 Slave 0 0 1 S T A R T C 1 C 0 A C K 1 0 0 1 Master Bus Address A 2 A 1 A 0 C 7 A C K C 6 Command and Status Register Address W C 5 C 4 C 3 C 2 Bus Address A 2 A 1 A 0 R A C K Master D 7 Slave D 6 D 5 Data (1) D 4 D 3 D 2 D 1 D 0 A C K D 7 D 6 D 5 D 2 D 1 D 0 A C K D 7 D 6 D 5 Data (n) D 4 D 3 D 2 D 1 D 0 N A C K S T O P Figure 26 - Command and Status Register Read S T A R T 1 Slave 0 0 1 S T A R T 0 0 0 A C K 1 0 0 1 Master Bus Address A 2 A 1 A 0 Channel Address C H 3 C H 2 C H 1 C H 0 Bus Address A 2 A 1 A 0 W A C K 0 R N A C K Master S T A R T 1 0 0 1 Bus Address A 2 A 1 A 0 Channel Address Echo C H 3 C H 2 C H 1 C H 0 D 9 D 8 A C K 0 D 7 10-Bit ADC Data D 6 D 5 D 4 D 3 D 2 D 1 D 0 N A C K S T O P R A C K 0 Slave Figure 27 – ADC Conversion Read Summit Microelectronics, Inc 2085 1.1 05/27/04 27 SMM465 Preliminary Information DEFAULT CONFIGURATION REGISTER SETTINGS – SMM465FC-249 Register R00 R01 R02 R03 R04 R05 R06 R07 R08 R09 R0A R0B R0C R0D R0E R0F R10 R11 R12 R13 R18 R19 R30 R31 R32 R33 R34 R35 R36 R37 R38 R39 R3A R3B R3C R3D R3E R40 R41 RC1 Contents 0D 83 0D FF 0E 61 0E C7 0F 54 0B 22 7F 0F 07 01 8F 9F AF BF 00 00 0D 60 0D DC 0E 45 0E A2 0F 08 0F D6 00 12 48 0D B9 Register R42 R43 R44 R45 R46 R47 R48 R49 R4A R4B R4C R4D R4E R80 R81 R82 R83 R84 R85 R86 R87 R88 R89 R8A R8B R8C R8D R8E R8F R90 R91 R92 R93 R94 R95 R96 R97 R98 R99 Contents 0E 39 0E A4 0F 16 0F B4 06 7F 00 12 50 42 48 82 3E 2A B8 12 F6 41 C8 81 B9 2A 34 12 49 49 5C 81 52 29 D7 11 EB 41 3E Register R9A R9B R9C R9D R9E R9F RA0 RA1 RA2 RA3 RA4 RA5 RA6 RA7 RA8 RA9 RAA RAB RAC RAD RAE RAF RB0 RB1 RB2 RB3 RB4 RB5 RB6 RB7 RB8 RB9 RBA RBB RBC RBD RBE RBF RC0 Contents 81 33 29 9A 11 AE 41 0B 80 F6 29 5D 11 71 40 CE 80 8F 29 1F 11 33 2A 67 0A 52 03 FF 03 FF 0D 9A 0D 56 0F E0 0F E0 0B Register RC1 RC2 RC3 RC4 RC5 RC6 RC7 RC8 RC9 RCA RCB RCC RCD RCE RCF RD0 RD1 RD2 RD3 RD4 RD5 RD6 RD7 RE0 RE1 RE2 RE3 RE4 RE5 RE6 RE7 RE8 RE9 REA REB Contents 38 0B 38 09 90 09 90 0C 00 0C 00 0F FF 0F FF 0C 00 0C 00 0F D8 0F D8 00 3D 00 3D 00 3D 00 3D 00 3D 00 3D The default device ordering number is SMM465FC-249. It is programmed with the register contents as shown above and tested over the commercial temperature range with a VREF setting of 1.25V. Other standard external VREF voltage settings that can be specified and tested are values of: 1.024, 1.225, 1.250, 2.048, 2.500, 3.000 or 3.300. The value is derived from the customer supplied hex file. New device suffix numbers are assigned to non-default requirements. If other VREF values are required, please contact a Summit Microelectronics Sales Representative. Application Note 47 contains a complete description of the Windows GUI and the default settings of each of the 154 individual Configuration Registers. Summit Microelectronics, Inc 2085 1.1 05/27/04 28 SMM465 Preliminary Information PACKAGE 48 PIN TQFP PACKAGE 0.354 (9.00) 0.276 (7.00) BSC (A) BSC (B) Inches (Millim eters) 0.02 (0.5) BSC 0.007 - 0.011 (0.17 - 0.27) DETAIL "A" (B) (A) Ref Jedec M S-026 0.037 - 0.041 0.95 - 1.05 Pin 1 Indicator 0.039 (1.00) Ref 0.047 MAX. (1.2) 0 o M in to 7 o M ax A B 0.002 - 0.006 (0.05-0.15) 0.018 - 0.030 (0.45 - 0.75) DETAIL "B" Summit Microelectronics, Inc 2085 1.1 05/27/04 29 SMM465 Preliminary Information PART MARKING SUMMIT SMM465F Annn xx Summit Part Number Status Tracking Code (Blank, MS, ES, 01, 02,...) (Summit Use) AYYWW Date Code (YYWW) Pin 1 Identifier Lot tracking code (Summit use) Part Number suffix (Contains Customer specific ordering requirements) Drawing not to scale Product Tracking Code (Summit use) ORDERING INFORMATION Summit Part Number SMM465 F C nnn Part Number Suffix (see page 28) Specific requirements are contained in the suffix such as Hex code, Hex code revision, etc. The calibrated VREF voltage settings are standard values of: 1.024, 1.225, 1.250, 2.048, 2.500, 3.000 or 3.300 Temp Range Package C=Commercial F=48 Lead TQFP Blank=Industrial NOTICE NOTE 1 - This is a Preliminary Information data sheet that describes a Summit product currently in pre-production with limited characterization. SUMMIT Microelectronics, Inc. reserves the right to make changes to the products contained in this publication in order to improve design, performance or reliability. SUMMIT Microelectronics, Inc. assumes no responsibility for the use of any circuits described herein, conveys no license under any patent or other right, and makes no representation that the circuits are free of patent infringement. Charts and schedules contained herein reflect representative operating parameters, and may vary depending upon a user’s specific application. While the information in this publication has been carefully checked, SUMMIT Microelectronics, Inc. shall not be liable for any damages arising as a result of any error or omission. SUMMIT Microelectronics, Inc. does not recommend the use of any of its products in life support or aviation applications where the failure or malfunction of the product can reasonably be expected to cause any failure of either system or to significantly affect their safety or effectiveness. Products are not authorized for use in such applications unless SUMMIT Microelectronics, Inc. receives written assurances, to its satisfaction, that: (a) the risk of injury or damage has been minimized; (b) the user assumes all such risks; and (c) potential liability of SUMMIT Microelectronics, Inc. is adequately protected under the circumstances. Revision 1.1 - This document supersedes all previous versions. Please check the Summit Microelectronics Inc. web site at www.summitmicro.com for data sheet updates. © Copyright 2004 SUMMIT MICROELECTRONICS, Inc. ADOC TM PROGRAMMABLE ANALOG FOR A DIGITAL WORLD™ is a registered trademark of Summit Microelectronics Inc., I2C is a trademark of Philips Corporation. Summit Microelectronics, Inc 2085 1.1 05/27/04 30