UC1910 UC2910 UC3910 4-Bit DAC and Voltage Monitor FEATURES DESCRIPTION • Precision 5V Reference • 4-Bit Digital-to-Analog (DAC) Converter • 0.5% DAC/Reference Combined Error The UC3910 is a complete precision reference and voltage monitor circuit for Intel Pentium® Pro and other high-end microprocessor power supplies. It is designed for use in conjunction with the UC3886 PWM. The UC3910 together with the UC3886 converts 5VDC to an adjustable output ranging from 2.0VDC to 3.5VDC in 100mV steps with 1% DC system accuracy. • Programmable Undervoltage and Overvoltage Fault Windows • Overvoltage Comparator with Complementary SCR Driver and Open Collector Outputs • Undervoltage Lockout The UC3910 utilizes thin film resistors to ensure high accuracy and stability of its precision circuits. The chip includes a precision 5V voltage reference which is capable of sourcing 10mA to external circuitry. The output voltage of the DAC is derived from this reference, and the accuracy of the DAC/reference combination is 0.5%. Programmable window comparators monitor the supply voltage to indicate that it is within acceptable limits. The window is programmed as a percentage centered around the DAC output. An overvoltage protection comparator is set at a percentage 2 times larger than the programmed lower overvoltage level and drives an external SCR as well as provides an open collector output. Undervoltage lockout protection assures the correct logic states at the outputs during power-up and power-down. BLOCK DIAGRAM UDG-95097-3 3/97 Powered by ICminer.com Electronic-Library Service CopyRight 2003 UC1910 UC2910 UC3910 CONNECTION DIAGRAM DIL-16, SOIC-16 (Top View) J, N, or D Packages ELECTRICAL CHARACTERISTICS Unless otherwise specified, VCC = 12V, VSENSE = 3.5V, VOVTH/UVTH = 1.26V, VD0 = VD1 = VD2 = VD3 = 0V, 0°C < TA < 70°C for the UC3910, –25°C < TA < 80°C for the UC2910, –55°C < TA < 125°C for the UC1910 TA = TJ. PARAMETER TEST CONDITIONS MIN TYP MAX UNITS Undervoltage Lockout VIN UVLO Turn-on Threshold 7 8 9 V UVLO Threshold Hysteresis 50 200 500 mV Supply Current IIN Startup VCC = 5V 2 3.5 mA IIN VCC = 12V 10 12 mA 0.9 % 1.5 % DAC/Reference DACOUT Voltage Accuracy D0-D3 Voltage High Line, Load, 0°C < TA < 70°C (Note 1) −0.9 Line, Load, –55°C < TA < 125°C –1.5 DX Pin Floating 4.6 4.85 D0-D3 Input Bias Current DX Pin Tied to GND –140 −105 VREF Output Voltage IVREF = 0mA, 0°C < TA < 70°C 4.97 5 Line, Load, 0°C < TA < 70°C (Note 1) 4.96 Line, Load, –55°C < TA < 125°C 4.925 VREF Total Variation VREF Sourcing Current V µA 5.03 V 5 5.04 V 5 5.075 V VREF = 0V 10 mA IDACBUF = –1mA, 0°C < TA < 70°C −25 25 mV –12 –1 mA DAC Buffer Input Offset Voltage Output Sourcing Current Monitor Circuitry (Note 2) VSENSE UV Threshold Voltage VSENSE OV Threshold Voltage Powered by ICminer.com Electronic-Library Service CopyRight 2003 Code 0, Ratio = 0.45 (Note 3) 3.174 3.237 3.3 V Code 0, Ratio = 0.9 2.87 2.975 3.08 V Code 15, Ratio = 0.45 1.816 1.85 1.884 V Code 15, Ratio = 0.9 1.635 1.7 1.765 V Code 0, Ratio = 0.45 3.7 3.763 3.826 V Code 0, Ratio = 0.9 3.92 4.025 4.13 V Code 15, Ratio = 0.45 2.116 2.15 2.184 V Code 15, Ratio = 0.9 1.635 2.3 2.365 V 2 UC1910 UC2910 UC3910 ELECTRICAL CHARACTERISTICS (cont.) Unless otherwise specified, VCC = 12V, VSENSE = 3.5V, VOVTH/UVTH = 1.26V, VD0 = VD1 = VD2 = VD3 = 0V, 0°C < TA < 70°C for the UC3910, –25°C < TA < 80°C for the UC2910, –55°C < TA < 125°C for the UC1910 TA = TJ. PARAMETER TEST CONDITIONS MIN TYP MAX UNITS 3.937 4.025 4.113 V Code 0, Ratio = 0.9 4.41 4.55 4.69 V Code 15, Ratio = 0.45 2.235 2.3 2.365 V Monitor Circuitry (Note 2) (cont.) VSENSE OVP Threshold Voltage Code 0, Ratio = 0.45 Code 15, Ratio = 0.9 2.505 2.6 2.695 V OV, UV Comparator Hysteresis Code 0, Ratio = 0.9 70 88 120 mV Code 15, Ratio = 0.45 15 25 40 mV OVP Comparator Hysteresis Code 0, Ratio = 0.9 160 218 300 mV Code 15, Ratio = 0.45 40 62 85 mV Input Common Mode Range OV, UV, OVP Comparators 0 5 V Propagation Delay OV, UV Comparators 5 µs OVP Comparator 5 µs PWRGOOD, OVP, OVPB Outputs PWRGOOD Voltage Low IPWRGOOD = 10mA OVP Sourcing Current VOVP = 1.4V OVPB Voltage Low IOVPB = 1mA 0.4 V 65 mA 0.4 V Note 1: "Line, Load" implies that the parameter is tested at all combinations of the conditions: 10.8V < VCC < 13.2V, –2mA < IVREF < 0mA. Note 2: These are the actual voltages on VSENSE which will cause the OVPB and PWRGOOD outputs to switch, assuming the DACOUT voltage is perfect. These limits apply for 0°C < TA < 70°C. Note 3: "Code 0" means pins D0 - D4 are all low; "Code 15" means they are all floating or high (See Table 1). "Ratio" is the divider ratio of the resistor string between DACBUF and OVTH/UVTH (See Figure 1). PIN DESCRIPTIONS Decimal Code 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 D0-D3 (DAC Digital Input Control Codes): These are the DAC digital input control codes, with D0 representing the least significant bit (LSB) and D3, the most significant bit (MSB) (See Table 1). A bit is set low by being connected to GND; a bit is set high by floating it, or connecting it to a 3V to 5V voltage source. Each control pin is pulled up to approximately 4.8V by an internal 40µA current source. DACBUF (Buffered DACOUT Voltage): This pin provides a buffered version of the DACOUT voltage to allow external programming of the OV/UV thresholds (see OVTH/UVTH below). DACOUT (Digital-to-Analog Converter Output Voltage): This pin is the output of the 4-bit digital to analog (DAC) converter. Setting all input control codes low produces 3.5V at DACOUT; setting all codes high produces 2.0V at DACOUT. The LSB step size (i.e. resolution) is 100mV (See Table 1). The DACOUT source impedance is typically 3kΩ and must therefore drive a high impedance input. Bypass DACOUT at the driven input with a 0.01µF, low ESR, low ESL capacitor for best circuit noise immunity. D2 D1 D0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 DACOUT Voltage 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 Table 1. Programming the DACOUT Voltage respect to GND. The two GND pins are connected together internally but should also be connected externally using a short PC board trace. Bypass capacitors on the VCC and VREF pins should be connected directly to the ground plane near one of the signal ground GND (Signal Ground): All voltages are measured with Powered by ICminer.com Electronic-Library Service CopyRight 2003 D3 3 UC1910 UC2910 UC3910 PIN DESCRIPTIONS (cont.) put): This pin is an open collector output which is driven low to reset the microprocessor when VSENSE rises above or falls below its nominal value by a percentage programmed by OVTH/UVTH. The OV and UV comparators’ hysteresis is a function of the DACBUF voltage and the OV/UV programmed percentage. pins. OVP (Overvoltage Comparator Output): This output pin drives an external SCR circuit with up to 65mA when the voltage on VSENSE rises above its nominal value by a percentage set by the voltage on the OVTH/UVTH pin (see below). The OVP comparator hysteresis is a function of both the DACBUF voltage and the OV/UV percentage programmed. VCC (Positive Supply Voltage): This pin supplies power to the chip. Connect VCC to a stable voltage source of at least 9V and capable of sourcing at least 15mA. The OVP and PWRGOOD outputs are held low, the OVPB output is in a high impedance state, and the VSENSE pin is pulled low until VCC exceeds the upper undervoltage lockout threshold. This pin should be bypassed directly to the GND pin with a 0.1µF low ESR, low ESL capacitor. OVPB (Overvoltage Comparator Complementary Output): This output is a complement to the OVP output (see above) and provides an open collector capable of sinking 1mA when the voltage on VSENSE rises above its nominal value by a percentage set by the voltage on the OVTH/UVTH pin (see below). OVTH/UVTH (Undervoltage and Lower Overvoltage Threshold Input): This pin is used to program the window thresholds for the OV and UV comparators. The OV-UV window is centered around the DACBUF voltage and can be programmed from ±5% to ±15% about DACBUF. Connect a resistor divider between DACBUF and GND to set the percentage. The threshold for the OVP comparator is internally set to a percentage 2 times larger than the programmed OV percentage; therefore, its range extends from 10% to 30% above DACBUF. VREF (Voltage Reference Output): This pin provides an accurate 5V reference, capable of delivering up to 10mA to external circuitry, and is internally short circuit current limited. For best reference stability, bypass VREF directly to the GND pin with a 0.1µF, low ESR, low ESL capacitor. VSENSE (Output Voltage Sensing Input): This pin is the input to the OVP and PWRGOOD comparators and is connected to the system output voltage through a lowpass filter. When choosing the resistor value for this filter, make sure that no more than 500µA will flow PWRGOOD (Undervoltage/Lower Overvoltage Out- APPLICATION INFORMATION The Overvoltage (OV), Undervoltage (UV) and Overvoltage Protection Voltage (OVP) threshold detection voltages are programmed as a percentage about the nominal DAC output voltage, DACOUT. Figure 1 illus- trates how to program the UC3910 by setting a voltage divider, RDIV, at the OVTH/UVTH pin. The voltage divider ratio is defined as RDIV = RS1 RS1 + RS2 The UC3910 allows a ratio RDIV at the OVTH/UVTH pin from 0.3 to 0.9, which corresponds to overvoltage and undervoltage percentage thresholds from 5% to 15% and an OVP percentage threshold from 10% to 30%. These thresholds are shown in Figure 2. The OV, UV and OVP percentage thresholds are given by %VOV = RDIV • 16.7 %VUV = –(RDIV • 16.7) %VOVP = %VOV • 2.0 = RDIV • 33.4 UDG-96020 An R-C filter is added to the VSENSE pin to filter noise and ripple at the comparator inputs. An R-C filter frequency of FSWITCH/10 is recommended. Choose the Figure 1. Setting the OV/UV/OVP Threshold Percentages Powered by ICminer.com Electronic-Library Service CopyRight 2003 4 UC1910 UC2910 UC3910 APPLICATION INFORMATION (cont.) 30 25 Thresholds (%) 20 OVP 15 OV 10 5 0 -5 UV -10 -15 0.3 0.4 0.5 0.6 0.7 0.8 0.9 Ratio RDIV UDG-96019 Figure 2. OV, UV and OVP Percentage Thresholds as a Function of the Divider Ratio RDIV Figure 3. Driving and SCR Using the UC3910 OVP Signal value of RF such that it limits the current into VSENSE to ≤ 0.5mA. The Overvoltage Protection output, OVP, can be used to directly drive a crowbarring SCR, as shown in Figure 3. RF • CF = RF ≥ 1 FSWITCH 2• π• 10 A typical application is shown in Figure 4 using the UC3910 together with the UC3886 Average Current Mode PWM Controller IC for a power supply to drive Intel’s Pentium®Pro processor. VOUT 0.5mA UDG-96021 Figure 4. UC3910 Configured with the UC3886 for a Pentium® Pro DC/DC Converter UNITRODE CORPORATION 7 CONTINENTAL BLVD. • MERRIMACK, NH 03054 TEL. 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