Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.
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Contents 1 Applications ........................................................................................................................ 7 1.1 2 Output Voltage Requirements ............................................................................................ 9 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 Power Good (Vcc_PWRGD - PROPOSED .......................................................................27 Voltage Regulator Hot (VR_hot#) - PROPOSED............................................
8.6 8.7 8.8 8.9 9 Shock and Vibration - PROPOSED .................................................................................. 34 Electromagnetic Compatibility - PROPOSED ................................................................... 34 Reliability - PROPOSED ................................................................................................... 34 Safety - PROPOSED ........................................................................................................
Revision History Document Number Revision Number 306760 001 Description • InitIal release of this document Date March 2005 NOTE: Not all revisions may be published. Guideline Categories REQUIRED: An essential part of the design – necessary to meet processor voltage and current specifications and follow processor layout guidelines. EXPECTED: Part of Intel’s processor power definitions; necessary for consistency among the designs of many systems and power devices.
Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.
1 Applications 1.1 Introduction and Terminology This document defines DC-to-DC converters to meet the power requirements of computer systems using 64-bit Intel® Xeon™ processor MP with up to 8MB L3 cache, 64-bit Intel® Xeon™ processor MP with 1MB L2 cache processors. Requirements will vary according to the needs of different computer systems and processors that a specific voltage regulator is expected to support.
Applications 8 Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.
2 Output Voltage Requirements 2.1 Voltage and Current - REQUIRED There will be independent selectable voltage identification (VID) codes for the core voltage regulator. The regulator’s 6-bit code (VID) will be provided by the processor to the VRM/EVRDs, which will determine a reference output voltage, as described in Section 3.2. Section 2.2 and Section 2.3 specify deviations from the VID reference voltage. The load line tolerance in Section 2.
Output Voltage Requirements baseboard temperatures. This includes voltage regulator layout, processor fan selection, ambient temperature, chassis configuration, etc. To avoid heat related failures, baseboards should be validated for thermal compliance under the envelope of system operating conditions. It is proposed that the voltage regulator thermal protection be implemented for all designs (Section 6.2).
Output Voltage Requirements Table 2-1. LL0, LL1 Codes LL0 LL1 0 0 Reserved 0 1 64-bit Intel® Xeon™ processor MP with up to 8MB L3 cache, 64-bit Intel® Xeon™ processor MP with 1MB L2 cache and mPGA604 Die Load Line 1 0 Reserved 1 1 Reserved LL0 LL1 0 0 0 1 1 2.3 1 0 1 Processor Vcc Tolerance / Load Line VccMAX = Reserved VccMIN = Reserved VccMAX = VID (V) – 1.25 m • Icc (A) VccMIN = VID (V) – 1.
Output Voltage Requirements 2.4 Stability - REQUIRED The VRM/EVRD needs to be unconditionally stable under all specified output voltage ranges, current transients of any duty cycle, and up to repetition rates of 1 MHz. The VRM/EVRD should be stable under a no load condition. 2.5 Processor Power Sequencing - REQUIRED The VRM/EVRD must support platforms with defined power-up sequences.
Output Voltage Requirements Figure 2-4. Power-On Sequence Timing Diagram Stage 1 90% of Vtt 1 Vtt 1ms
Output Voltage Requirements condition, followed by an increased activity level. Transition 34 is a simplification of the multiple steps from the high-voltage load line to the low-voltage load line. Transition 45 is an example of a response to a load change during normal operation in the lower range. Figure 2-5. Processor Transition States VID High Load Line 2 A 3 Icc-max 5 VID Low Load Line 1 4 B Figure 2-6 is an example of dynamic VID.
Output Voltage Requirements The processor load may not be sufficient to absorb all of the energy from the output capacitors on the baseboard, when VID changes to a lower output voltage. The VRM/EVRD design should ensure that any energy transfer from the capacitors does not impair the operation of the VRM/EVRD, the AC-DC supply, or any other parts of the system. 2.
Output Voltage Requirements Figure 2-7. 64-bit Intel® Xeon™ Processor MP with up to 8MB L3 Cache Load Model VR Socket and Package Pins Baseboard 0.5m 30 pH 36 X 10 uF 1206 MLCC 12 X 560 uF Aluminum-Polymer 6720 uF 360 uF 80 uF 0.58m 0.28m 1.25m 333 pH 33 pH 35pH 8 X 10 uF 1206 MLCC 0.34m Die Sense Point PWL 150 pH Figure 2-8.
Output Voltage Requirements NOTE: 1. Only the decoupling caps inside the socket cavity need to have the temperature coefficient of “X6S”. In Figure 2-7 and Figure 2-8 the impedance values labeled “mPGA604 Socket and Package Pins” are supplied by Intel Corporation and are beyond the control of the system designer. It is recommended that the system designer work with the VRM supplier to ensure proper implementation of the VRM converter. 2.
Output Voltage Requirements 18 Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.
3 Control Signals 3.1 Output Enable (OUTEN) - REQUIRED The VRM/EVRD should accept an input signal to enable its output voltage. When disabled, the regulator’s output should go to a high impedance state and should not sink or source current. When OUTEN is pulled low during the shutdown process, the VRM/EVRD should not exceed the previous voltage level regardless of the VID setting during the shutdown process. Once operating after power-up, it should respond to a deasserted OUTEN within 500 ms.
Control Signals Table 3-3. Voltage Identification (VID) Processor Pins (0 = low, 1 = high) VID4 VID3 VID2 VID1 VID0 VID5 0 1 0 1 0 0 0 1 0 0 1 0 1 0 0 1 0 1 0 0 0 1 0 0 0 0 0 0 Vout (V) Processor Pins (0 = low, 1 = high) Vout (V) VID4 VID3 VID2 VID1 VID0 VID5 0.8375 1 1 0 1 0 0 1.2125 1 0.8500 1 1 0 0 1 1 1.2250 0 0.8625 1 1 0 0 1 0 1.2375 0 1 0.8750 1 1 0 0 0 1 1.2500 0 0 0 0.8875 1 1 0 0 0 0 1.2625 1 1 1 1 0.
Control Signals 3.3 Differential Remote Sense (VO_SEN+/-) - REQUIRED The PWM controller should include differential sense inputs to compensate for an output voltage offset of <300 mV in the power distribution path. This common mode voltage is expected to occur due to transient currents and parasitic inductances and is not expected to be caused by parasitic resistances. The remote sense lines should draw no more than 10 mA, to minimize offset errors. Note: 3.
Control Signals 22 Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.
4 Input Voltage and Current 4.1 Input Voltages - EXPECTED The power source for the VRM/EVRD is 12V +5% / –8%. This voltage is supplied by a separate power supply. For input voltages outside the normal operating range, the VRM/EVRD should either operate properly or shut down. 4.2 Load Transient Effects on Input Current EXPECTED The design of the VRM/EVRD, including the input power delivery filter, must ensure that the maximum slew rate of the input current does not exceed 0.
Input Voltage and Current 24 Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.
5 Processor Voltage Output Protection These are features built into the VRM/EVRD to prevent damage to itself, the processor, or other system components. 5.1 Over-Voltage Protection (OVP) - PROPOSED The OVP circuit monitors the processor core voltage (Vcc) for an over-voltage condition. If the output is more than 200 mV above the VID level, the VRM/EVRD shuts off the output. 5.
Processor Voltage Output Protection 26 Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.
6 Output Indicators 6.1 Power Good (Vcc_PWRGD - PROPOSED The VRM/EVRD may provide a power-good output signal, which remains in the low state until a maximum of 10 ms after the output voltage reaches the range specified in Section 2.2. The signal should then remain asserted as long as the VRM/EVRD output is operating within specification. It will be an open-collector/drain or equivalent signal. The pull-up resistor and voltage source will be located on the baseboard.
Output Indicators It is recommended that hysteresis be designed into the thermal sense circuit to prevent a scenario in which the VR_hot# signal is rapidly being asserted and de-asserted. 6.3 Load Indicator Output (Load Current) - PROPOSED The VRM/EVRD may have an output with a voltage (Load Current) level that varies linearly with the VRM/EVRD output current. The PWM controller supplier may specify a voltage-current relationship consistent with the controller’s current sensing method.
7 VRM – Mechanical Guidelines 7.1 VRM Connector - EXPECTED The part number and vendor name for the connector can be found in Table 7-1. The VRM interface with the system board is a 27-pin pair edge connector. The connector uses latches to hold the VRM in place. The connector will be rated to handle a continuous load current of 130 A. Table 7-1. VRM 10.
VRM – Mechanical Guidelines Table 7-2. VRM 10.
VRM – Mechanical Guidelines Table 7-3. VRM 10.2 Pin Assignments KEY KEY KEY 7.
9 .0 3 m m (0 . 3 5 6 " ) MAX 1 3 .1 8 m m (0 . 5 1 9 " ) 3 .0 0 m m ( 0 .1 1 8 ") 1 3 .5 0 m m (0 . 5 3 1 " ) P IN 1 3 .3 3 m m (0 .1 3 1 " ) P IN 5 4 P IN 1 P IN 5 4 1 5 .5 0 m m ( 0 .6 1 0 ") 5 1 .8 4 m m ( 2 . 0 4 ”) V ie w A 2 8 .9 m m ( 1 .1 3 8 ") 7 .8 7 m m ( 0 .3 1 0 ") 8 x 2 .5 0 m m (0 .0 9 8 " ) P C B F o o tp r i n t 5 .0 8 m m (0 . 2 0 0 " ) P IN 2 8 2 0 .0 m m ( 0 . 7 9 ") 6 5 .3 4 m m ( 2 .5 7 " ) MAX R 0 .6 5 m m ( R 0 .0 2 6 ") V iew B 1 .8 0 m m (0 .
8 VRM – Environmental Conditions The VRM design, including materials, should be consistent with the manufacture of units that meet the environmental requirements specified below; 8.1 Operating Temperature - PROPOSED The VRM shall meet all electrical requirements when operated at Thermal Design Current (Icc (TDC)) over an ambient temperature range of 0º C to +45º C with a minimum airflow of 400 LFM. The volumetric airflow (Q) can be measured through a wind tunnel.
VRM – Environmental Conditions 8.5 Electrostatic Discharge - PROPOSED Testing shall be in accordance with IEC 61000-4-2. Operating – 15 kV initialization level. The direct ESD event shall cause no out-of-regulation conditions – including overshoot, undershoot and nuisance trips of over-voltage protection, overcurrent protection or remote shutdown circuitry. Non-operating –25 kV initialization level. The direct ESD event shall not cause damage to the VRM circuitry. 8.
9 Lead Free (Pb Free) The use of lead in electronic products is an increasingly visible environmental and political concern. The drivers for the reduction or elimination of lead in electronic products include: • • • • Customer desire for environmentally friendly (‘green’) products. Manufacturer desire to be environmentally friendly, and be perceived as such. Government initiatives regarding recycling of electronic products. Planned and potential legislation.
Lead Free (Pb Free) 36 Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.