TS3004 Demo Board A 1.55V to 5.25V, 1.9A, 3.3s to 233s Silicon Timer FEATURES DESCRIPTION The TS3004 is a single-supply, second-generation oscillator/timer fully specified to operate at a supply voltage range of 1.55V to 5.25V while consuming less than 2.4A(max) supply current. Requiring only a resistor to set the base output frequency (or output period) at 25kHz (or 40s) with a 50% duty cycle, the TS3004 timer/oscillator is compact, easy-to-use, and versatile. Optimized for ultra-long life, low frequency, battery-powered/portable applications, the TS3004 joins the TS3001, TS3002, TS3003 and TS3006 in the CMOS timer family of the "NanoWatt AnalogTM" series of high-performance analog integrated circuits. 5V Supply Voltage FOUT/PWMOUT Output Period Range: o 40s tFOUT 1.398min o RSET = 4.32M PWMOUT Output Duty Cycle: o 75% for FDIV2:0 = 000 o CPWM = 100pF PWMOUT Duty Cycle Reduction o 1M Potentiometer Fully Assembled and Tested 2in x 2in 2-layer circuit board COMPONENT LIST DESIGNATION QTY DESCRIPTION C1 1 C2 1 R2 R1 PWM_ADJ U1 VDD,F_OUT, PWM_OUT J1, FDIV0, FDIV1, FDIV2 1 1 1 1 3 100pF 10% capacitor (0805) 4.7F 10% capacitor (0805) 10M 1% (0805) 4.32M 1% (0805) 1M Potentiometer TS3004 Test points 3 Jumper The TS3004 requires only an RSET = 4.32M resistor to set the FOUT/PWMOUT output period range to between 40s and 1.398 minutes. To change the output period, an FDIV2:0 combination can be selected. With an on-board 100pF CPWM capacitor, the duty cycle of PWMOUT is set at approximately 75%. Further reduction of the duty cycle is available with an on-board 1M potentiometer. The complete circuit is designed at a supply voltage of 5V. The TS3004 is fully specified over the -40C to +85C temperature range and is available in a low-profile, 10-pin 3x3mm TDFN package with an exposed back-side paddle. Product data sheet and additional documentation can be found at www.silabs.com. ORDERING INFORMATION Order Number TS3004DB Figure 1. TS3004 Demo Board (Top View) Description TS3004 Demo Board Figure 2. TS3004 Demo Board (Bottom View) Page 1 (c) 2014 Silicon Laboratories, Inc. All rights reserved. TS3004 Demo Board DESCRIPTION The TS3004 requires only an RSET = 4.32M resistor to set the FOUT/PWMOUT output period between 40s and 1.398 minutes. To change the output period, an FDIV2:0 combination can be selected. With an on-board 100pF CPWM capacitor, the duty cycle of PWMOUT is set at approximately 75%. Further reduction of the duty cycle is available with an on-board 1M potentiometer. The complete circuit is designed at a supply voltage of 5V and it is shown in Figure 1. where ICPWM and VCPWM is the current supplied and voltage applied to the CPWM capacitor, respectively. The pulse width is determined based on the period of FOUT and should never be greater than the period at FOUT. Make sure the PWM_CNTRL pin is set to at least 400mV when calculating the pulse width of PWMOUT. Note VCPWM is approximately 300mV, which is the RSET voltage. Also note that ICPWM is either 1A or 100nA. Refer to Table 2 for the output period range available with a 10M RSET resistor. ICPWM FDIV tFOUT (A) 2:0 000 40s 1 001 320s 1 010 2560s 100n 011 20.48ms 100n 100 163.84ms 100n 101 1.310s 100n 110 10.486s 100n 111 1.398min 100n Table 2: FOUT and PWMOUT Frequency Range per FDIV2:0 Combination for RSET= 4.32M The TS3004 is a user-programmable oscillator where the period of the square wave at its FOUT terminal is generated by an external resistor connected to the RSET pin. The output period is given by: tFOUT (s) = 8FDIV2:0 x 4.32M 1.08E11 Equation 1. FOUT Frequency Calculation where FDIV2:0 = 0 to 7 With RSET = 4.32M and FDIV2:0=000(0), the FOUT period is approximately 40s with a 50% duty cycle. As design aids, Tables 1 lists TS3004's typical FOUT period for various standard values for RSET and FDIV2:0 = 111(7). RSET (M) tFOUT(s) 0.360 6.99 1 19.42 2.49 48.35 4.32 83.89 6.81 132.27 9.76 189.39 12 233 Table 1: tFOUT vs RSET for FDIV2:0 = 111(7) The TS3004 also provides a separate PWM output signal at its PWMOUT terminal that is anti-phase with respect to FOUT. To adjust the pulse width of the PWMOUT output, a single capacitor can be placed at the CPWM pin. To determine the capacitance needed for a desired pulse width, the following equation is to be used: Pulse Width(s) x ICPWM CPWM(F)= VCPWM 300mV The PWMOUT output pulse width can be adjusted further after selecting a CPWM capacitor. This can be achieved by applying a voltage to the PWM_CNTRL pin between VRSET and GND. With a voltage of at least VRSET, the pulse width is set based on Equation 2. For example, with a period of 40s and a 0.1F capacitor at the CPWM pin generates a pulse width of approximately 30ms. This can be calculated using Equation 2. By reducing the PWM_CNTRL voltage from VRSET 300mV to GND, the pulse width can be reduced further. Note that VRSET can be set up to VDD. QUICK START PROCEDURE Required Equipment TS3004 Demo Board DC Power Supply Oscilloscope equivalent Two 10X, 15pF//10M oscilloscope probes Potentiometer screwdriver Model Agilent DSO1014A or Equation 2. CPWM Capacitor Calculation TS3004-EVB Rev. 1.0 Page 2 TS3004 Demo Board To evaluate the TS3004 silicon timer, the following steps are to be performed: 1) Before connecting the DC power supply to the demo board, turn on the power supply, set the DC voltage to 5V, and then turn it off. 2) Connect the DC power supply positive terminal to the test point labeled VDD. Connect the negative terminal of the DC power supply to the test point labeled GND. 3) To monitor the FOUT output signal, connect the signal terminal of an oscilloscope probe to the test point labeled FOUT and the ground terminal to the test point labeled GND. 4) To monitor the PWMOUT output signal, connect the signal terminal of a second oscilloscope probe to the test point labeled PWM_OUT and the ground terminal to the test point labeled GND. 5) Select two channels on the oscilloscope and set the vertical voltage scale and the vertical position on each channel to 2V/DIV and 0V, respectively. Set the horizontal time scale to 5s/DIV. The coupling should be DC coupling. Turn on the power supply. The supply current will vary depending on the load on the output. Given the default set-up on the board, the FOUT/PWMOUT output period is approximately 40s. The PWMOUT duty cycle is set to approximately 75%. With an output load of 15pF on both FOUT and PWMOUT outputs due to the oscilloscope probes, the supply current should be less than 8A. 6) To change the period, change the combination of FDIV2:0 via jumpers FDIV2, FDIV1, and FDIV0. Refer to Table 2. 7) If further reduction of the duty cycle of the PWMOUT output is desired, turn the potentiometer clockwise. If jumper J1 is removed, the PWM_CNTRL pin is tied to VDD and the potentiometer will not change the PWMOUT output duty cycle. Figure 3. TS3004 Demo Board Circuit TS3004-EVB Rev. 1.0 Page 3 TS3004 Demo Board Period vs RSET 120 PERIOD - s 100 80 60 40 20 0 0 2 4 6 8 10 12 RSET - M Figure 4. FOUT/PWMOUT Period vs RSET Figure 5. Top Layer View #1 Figure 6. Top Layer View #2 Figure 7. Bottom Layer (GND) #2 Figure 8. Bottom Layer (GND) #2 Page 4 Silicon Laboratories, Inc. 400 West Cesar Chavez, Austin, TX 78701 +1 (512) 416-8500 www.silabs.com TS3004-EVB Rev. 1.0 Smart. Connected. Energy-Friendly Products Quality Support and Community www.silabs.com/products www.silabs.com/quality community.silabs.com Disclaimer Silicon Laboratories intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software implementers using or intending to use the Silicon Laboratories products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific device, and "Typical" parameters provided can and do vary in different applications. Application examples described herein are for illustrative purposes only. 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