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HA7210IBZ96 Datasheet(PDF) 4 Page - Intersil Corporation |
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HA7210IBZ96 Datasheet(HTML) 4 Page - Intersil Corporation |
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4 / 15 page  4 Test Circuit In production the HA7210 is tested with a 32kHz and a 1MHz crystal. However for characterization purposes data was taken using a sinewave generator as the frequency determining element, as shown in Figure 1. The 1VP-P input is a smaller amplitude than what a typical crystal would generate so the transitions are slower. In general the Generator data will show a “worst case” number for IDD, duty cycle, and rise/fall time. The Generator test method is useful for testing a variety of frequencies quickly and provides curves which can be used for understanding performance trends. Data for the HA7210 using crystals has also been taken. This data has been overlaid onto the generator data to provide a reference for comparison. Application Information Theory Of Operation The HA7210 is a Pierce Oscillator optimized for low power consumption, requiring no external components except for a bypass capacitor and a Parallel Mode Crystal. The Simplified Block Diagram shows the Crystal attached to pins 2 and 3, the Oscillator input and output. The crystal drive circuitry is detailed showing the simple CMOS inverter stage and the P-channel device being used as biasing resistor RF. The inverter will operate mostly in its linear region increasing the amplitude of the oscillation until limited by its transconductance and voltage rails, VDD and VRN. The inverter is self biasing using RF to center the oscillating waveform at the input threshold. Do not interfere with this bias function with external loads or excessive leakage on pin 2. Nominal value for RF is 17MΩ in the lowest frequency range to 7M Ω in the highest frequency range. The HA7210 optimizes its power for 4 frequency ranges selected by digital inputs Freq1 and Freq2 as shown in the Block Diagram. Internal pull up resistors (constant current 0.4 µA) on Enable, Freq1 and Freq2 allow the user simply to leave one or all digital inputs not connected for a corresponding “1” state. All digital inputs may be left open for 10kHz to 100kHz operation. A current source develops 4 selectable reference voltages through series resistors. The selected voltage, VRN, is buffered and used as the negative supply rail for the oscillator section of the circuit. The use of a current source in the reference string allows for wide supply variation with minimal effect on performance. The reduced operating voltage of the oscillator section reduces power consumption and limits transconductance and bandwidth to the frequency range selected. For frequencies at the edge of a range, the higher range may provide better performance. The OSC OUT waveform on pin 3 is squared up through a series of inverters to the output drive stage. The Enable function is implemented with a NAND gate in the inverter string, gating the signal to the level shifter and output stage. Also during Disable the output is set to a high impedance state useful for minimizing power during standby and when multiple oscillators are OR’ed to a single node. Design Considerations The low power CMOS transistors are designed to consume power mostly during transitions. Keeping these transitions short requires a good decoupling capacitor as close as possible to the supply pins 1 and 4. A ceramic 0.1 µF is recommended. Additional supply decoupling on the circuit board with 1 µF to 10µF will further reduce overshoot, ringing and power consumption. The HA7210, when compared to a crystal and inverter alone, will speed clock transition times, reducing power consumption of all CMOS circuitry run from that clock. Power consumption may be further reduced by minimizing the capacitance on moving nodes. The majority of the power will be used in the output stage driving the load. Minimizing the load and parasitic capacitance on the output, pin 5, will play the major role in minimizing supply current. A secondary source of wasted supply current is parasitic or crystal load capacitance on pins 2 and 3. The HA7210 is designed to work with most available crystals in its frequency range with no external components required. Two 15pF capacitors are internally switched onto crystal pins 2 and 3 on the HA7210 to compensate the oscillator in the 10kHz to 100kHz frequency range. The supply current of the HA7210 may be approximately calculated from the equation: IDD = IDD(Disabled) + VDD × fOSC × CL where: IDD = Total supply current VDD = Total voltage from VDD (pin 1) to VSS (pin 4) fOSC = Frequency of Oscillation CL = Output (pin 5) load capacitance EXAMPLE #1: VDD = 5V, fOSC = 100kHz, CL = 30pF IDD(Disabled) = 4.5µA (Figure 10) IDD = 4.5µA + (5V)(100kHz)(30pF) = 19.5µA Measured IDD = 20.3µA EXAMPLE #2: VDD = 5V, fOSC = 5MHz, CL = 30pF IDD (Disabled) = 75µA (Figure 9) IDD = 75µA + (5V)(5MHz)(30pF) = 825µA Measured IDD = 809µA 1 2 3 4 8 7 6 5 HA7210 VOUT CL +5V 18pF 0.1 µF 1000pF 50 Ω ENABLE FREQ 2 FREQ 1 1VP-P FIGURE 1. HA7210 |
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