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AD9523 Datasheet(PDF) 41 Page - Analog Devices |
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AD9523 Datasheet(HTML) 41 Page - Analog Devices |
41 / 60 page Data Sheet AD9523 Rev. D | Page 41 of 60 POWER DISSIPATION AND THERMAL CONSIDERATIONS The AD9523 is a multifunctional, high speed device that targets a wide variety of clock applications. The numerous innovative features contained in the device each consume incremental power. If all outputs are enabled in the maximum frequency and mode that have the highest power, the safe thermal operating conditions of the device may be exceeded. Careful analysis and consideration of power dissipation and thermal management are critical elements in the proper application of the AD9523 device. The AD9523 device is specified to operate within the industrial temperature range of –40°C to +85°C. This specification is conditional, however, such that the absolute maximum junction temperature is not exceeded (as specified in Table 17). At high operating temperatures, extreme care must be taken when operating the device to avoid exceeding the junction temperature and potentially damaging the device. A maximum junction temperature is listed in Table 1 with the ambient operating range. The ambient range and maximum junction temperature specifications ensure the performance of the device, as guaranteed in the Specifications section. Many variables contribute to the operating junction temperature within the device, including • Selected driver mode of operation • Output clock speed • Supply voltage • Ambient temperature The combination of these variables determines the junction temperature within the AD9523 device for a given set of operating conditions. The AD9523 is specified for an ambient temperature (TA). To ensure that TA is not exceeded, an airflow source can be used. Use the following equation to determine the junction temperature on the application PCB: TJ = TCASE + (ΨJT × PD) where: TJ is the junction temperature (°C). TCASE is the case temperature (°C) measured by the user at the top center of the package. ΨJT is the value from Table 18. PD is the power dissipation of the AD9523. Values of θJA are provided for package comparison and PCB design considerations. θJA can be used for a first-order approximation of TJ by the equation TJ = TA + (θJA × PD) where TA is the ambient temperature (°C). Values of θJC are provided for package comparison and PCB design considerations when an external heat sink is required. Values of ΨJB are provided for package comparison and PCB design considerations. CLOCK SPEED AND DRIVER MODE Clock speed directly and linearly influences the total power dissipation of the device and, therefore, the junction temperature. Two operating frequencies are listed under the incremental power dissipation parameter in Table 3. Using linear interpretation is a sufficient approximation for frequencies not listed in the table. When calculating power dissipation for thermal consideration, the amount of power dissipated in the 100 Ω resistor must be removed. If using the data in Table 2, this power is already removed. If using the current vs. frequency graphs provided in the Typical Performance Characteristics section, the power into the load must be subtracted, using the following equation: Ω 100 2 Swing Voltage Output al Differenti EVALUATION OF OPERATING CONDITIONS The first step in evaluating the operating conditions is to determine the maximum power consumption (PD) internal to the AD9523. The maximum PD excludes power dissipated in the load resistors of the drivers because such power is external to the device. Use the power dissipation specifications listed in Table 3 to calculate the total power dissipated for the desired configuration. The base typical configuration parameter in Table 3 lists a power of 428 mW, which includes one LVPECL output at 122.88 MHz. If the frequency of operation is not listed in Table 3, see the Typical Performance Characteristics section, current vs. frequency and driver mode to calculate the power dissipation; then add 20% for maximum current draw. Remove the power dissipated in the load resistor to achieve the most accurate power dissipation internal to the AD9523. See Table 30 for a summary of the incremental power dissipation from the base power configuration for two different examples. Table 30. Temperature Gradient Examples Description Mode Frequency (MHz) Maximum Power (mW) Example 1 Base Typical Configuration 428 Output Driver 6 × LVPECL 122.88 330 Output Driver 6 × LVDS 245.76 110 Total Power 868 Example 2 Base Typical Configuration 428 Output Driver 13 × LVPECL 983.04 2066 Total Power 2500 The second step is to multiply the power dissipated by the thermal impedance to determine the maximum power gradient. For this example, a thermal impedance of θJA = 20.1°C/W was used. |
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