HA16117FPAJ

HA16117F Series CMOS Watchdog Timer REJ03F0142-0300 (Previous: ADE-204-018B) Rev.3.00 Jun 15, 2005 Description The HA16117F Series of ICs make a micro-processor (MPU) system fail-safe by monitoring its power supply to detect voltage drops, and monitoring a P-RUN (program running) pulse to detect system crashes. Also referred to as watchdog timers, these devices are essential in systems that aim for high levels of crash protection. Fabricated by a CMOS process, they consume little power and are ideally suited for battery-operated systems. These ICs are available in versions for industrial and communications equipment and automotive applications, as well as for consumer products. Functions • ower-on reset Sends a RES signal to the MPU for a fixed time at power-on • Watchdog timer (WDT) Monitors a P-RUN signal from the MPU and sends the MPU a RES signal if P-RUN departs from a set frequency range • Auto-reset Outputs RES signals to the MPU at clocked intervals while P-RUN remains abnormal • Supply voltage supervision Outputs a low RES signal if the supply voltage (same as the MPU's VCC) falls below a low threshold level (VTL). The threshold differs for different ICs in the series, allowing designers to choose an IC matching system requirements (see ordering information) Features • Low power consumption • • • • • : Operating (ACC pin low) = 0.5 mW (Typ) : Standby (ACC pin high) = 0.2 mW (Typ) Watchdog timer on/off control by ACC input signal Independent auto-reset high and low times (tRH and tRL) Watchdog monitoring by frequency filtering (independent of duty cycle) High-precision low voltage detection (±2%) Space- and weight-saving 8-pin SOP package Ordering Information The HA16117F Series includes three ICs with different low threshold levels (VTL). Type No. HA16117FPA/FPAJ HA16117FPB/FPBJ HA16117FPC/FPCJ 4.4 V Typ 4.2 V Typ 4.0 V Typ Low Threshold Voltage (VTL) Rev.3.00 Jun 15, 2005 page 1 of 30 HA16117F Series Pin Arrangement VCC P-RUN CF CR 1 2 3 4 8 7 6 5 Tadj ACC GND RES (Top view) Pin Description Pin No. 1 2 3 4 5 6 7 VCC P-RUN CF CR RES GND ACC Symbol Power supply voltage input Watchdog timer (WDT) input Connected capacitor CF determines WDT filter characteristic (normal frequency range) Connected capacitor CR determines tON for power-on reset and tOFF, tRH, and tRL for auto-reset Reset signal output from WDT and voltage supervision circuits Ground WDT on/off control input (on when ACC is low) Function 8 Tadj * For adjusting tRH and tOFF (divide VCC to get the adjustment voltage) Note: The low-voltage threshold cannot be modified by changing the external resistors connected to the Tadj pin. Rev.3.00 Jun 15, 2005 page 2 of 30 HA16117F Series Block Diagram 5V GND VCC 1 2.52 (117FA) 2.36 (117FB) 2.20 (117FC) Low voltage detector − + 6 1 GND ≈1.25 V COMP. RES 0.1 µ 4 CR Power-on and auto-reset circuit (*I1 < I2) SW2 I2 adjustment I2 I1 − + 5 to Microcomputer COMP. SW1 R1 510 k 8 R2 750 k Tadj (SW1 and SW2 are active high) Watchdog timer Watchdog filter (f-duty converter) W.D out duty (%) Normal range W.D out fL/2 fH/2 duty n% P-RUN 1/2 frequency W.D in 2 divider duty 50% n W.D in frequency (Hz) 3 PULSE from I/O port Mode Operating Standby ACC Voltage Low High Function Low voltage detection and WDT Low voltage detection CF 0.01 µ 7 ACC Operating: "Low" Standby: "High" Note: The power-on reset circuit operates in both operating and standby modes. The HA16117F consists of a low voltage detector, power-on and auto-reset circuit, and watchdog timer. Low Voltage Detector Uses a reference voltage source (≈ 1.25 V) and high-precision comparator to detect drops in the supply voltage. Power-On and Auto-Reset Circuit Generates the RES waveform, using a multivibrator consisting of a current source I1 that charges the external capacitor CR, a current source I2 that discharges CR, and a comparator. Watchdog Timer Reshapes the P-RUN signal (programming-running pulse) from the MPU to obtain a 50% duty cycle, then converts frequency to duty cycle in the watchdog filter (WD filter). The watchdog filter is a bandpass filter. The duty cycle of the filter output is highest in the normal frequency range of PRUN. The watchdog filter output controls I2 in the multivibrator, the higher the duty cycle of the watchdog filter output, the shorter the time during which I2 discharges CR. If the duty cycle is high enough then CR is held at a high potential, preventing the multivibrator from firing, and the RES output remains high. Rev.3.00 Jun 15, 2005 page 3 of 30 HA16117F Series Absolute Maximum Ratings (Ta = 25°C) Item Power supply voltage P-RUN input voltage ACC input voltage RES output current Permissible dissipation * Operating temperature range 1 Symbol VCC VP VACC IRES PT Topr Ratings HA16117FPA/FPB/FPC HA16117FPAJ/FPBJ/FPCJ –0.3 to +14 VCC 14 10 300 –30 to +85 –0.3 to +14 VCC 14 10 300 –40 to +85 Unit V V V mA mW °C Storage temperature Tstg –55 to +125 –55 to +125 °C Note: 1. This is the value when mounted on a glass epoxy substrate with 30% wiring density, up to an ambient temperature of 83°C. Above that temperature, derate by 7.14 mW/°C. 40mm Substrate Permissible dissipation PT (mW) 0.8 mm ceramic or 1.5 mm epoxy 400 300 200 100 83°C −7.14 mW/°C (30% wiring density) 85°C 0 −30 −20 0 20 40 60 80 100 Ambient operating temperature range Ta (°C) Rev.3.00 Jun 15, 2005 page 4 of 30 HA16117F Series Electrical Characteristics (VCC = 5 V, Ta = 25°C, CF = 0.01 µF, CR = 0.1 µF, R1 = 510 kΩ, R2 = 750 kΩ) General Item Operating supply current Symbol ICC1 ICC2 Min – – – Typ 100 200 43 Max – 600 100 Unit µA µA µA Test Conditions VACC = 0 V, fP-RUN = 100 Hz VACC = 0 V, fP-RUN = 20 kHz Standby supply current Low voltage detector ACC P-RUN input WDT Low voltage threshold level Hysteresis width Low input voltage High input voltage Low input voltage High input voltage Power-on reset time Reset-clock off time Reset low time Reset high time Low setup time High setup time HA16117FPA/FPAJ HA16117FPB/FPBJ HA16117FPC/FPCJ ISTBY VACC = 12 V When VCC drops VTL 4.3 4.1 3.9 50 – 4.4 4.2 4.0 100 – – – – 4.5 4.3 4.1 150 V V V mV VHYS VIL1 VIH1 VIL2 VIH2 tON 1 tOFF * tRL tRH tSL tSH VOL VOH VRES K 0.8 – 2.0 – V V V V ms ms ms ms ms ms V V V – 0.8 – 2.0 24 78 12 36 1 – – – – 40 130 20 60 – – – 56 182 28 84 – P-RUN pin = 0 V 1 0.4 – RES output Constant range RES low voltage RES high voltage Reset function starting voltage Constant range of R1 and R2 VCC 0.8 0.6 IOL = 1 mA Open K =R2 / (R1 + R2) 0.55 1.4 0.8 6.0 Operating supply voltage range VCCRNG VTL – Note: 1. Reset-clock off time tOFF is provided a shown in the under figure. V f = 500 Hz, Duty = 50% P-RUN RES tOFF Rev.3.00 Jun 15, 2005 page 5 of 30 HA16117F Series Timing Waveforms and Functional Description VTL VCC P-RUN Crash t RH Watchdog function on RES (VACC = "Low") t ON t OFF t ON t RL Watchdog function off RES (VACC = "High") t ON t ON Figure 1 Timing Waveforms Watchdog On/Off Function A feature of the HA16117F is that watchdog supervision can be switched on and off. When the watchdog function is switched on, both the supply voltage and P-RUN input are monitored to detect abnormal conditions. When the watchdog function is switched off (standby mode), only the supply voltage is monitored. Watchdog supervision is switched on and off by the input at the ACC pin (pin 7): Supervision is on when ACC is low, and off when ACC is high. Many MPUs have a standby mode in which the CPU stops running but memory contents are retained. In standby mode, program execution halts and I/O ports go to the high-impedance state, so there is no need for the watchdog timer to supervise pulse output from an I/O port to detect abnormal conditions. Power can be saved by placing both the MPU and HA16117F in standby mode at the same time. The HA16117F is designed to draw a typical standby current I STBY of only 43 µA Typ when the watchdog function is switched off. ACC Pin (pin 7) and RES Output When the MPU returns from standby mode to normal operation it generally takes 10 to 200 ms for the clock oscillator in the MPU to stabilize. The RES signal is not output during this setup time. After the setup time (tSL) has elapsed, RES is output if the P-RUN signal from the MPU is still abnormal. ACC pin Adjust according to MPU's setup time t SH RES (due to MPU crash) t SL Figure 2 ACC Pin and RES Output Rev.3.00 Jun 15, 2005 page 6 of 30 HA16117F Series Internal Operation and Usage Notes Figure 3 shows an equivalent circuit of the watchdog timer block with a VCC pin level of 5 V and ACC pin level of 0 V, and the following pages show internal operation timing charts for different P-RUN frequencies. (Descriptions apply to conditions CF = 0.01 µF, CR = 0.1 µF, R2/(R1 + R2) = 0.6.) Operation The power-on and auto-reset circuit is a multivibrator with timing controlled by CR charge current I1 and discharge current I2. As I1 : I2 ≈ 3 : 1 (Typ design value), when the (WD) (watchdog filter circuit output) on-duty is 25% or above, the CR pin potential does not fall below 1.6 V. Therefore, (C) in the figure below is fixed low, and RES is not output. The (WD) on-duty varies according to the P-RUN frequency. If the frequency is lower or higher than the design value, the (WD) on-duty decreases, and at 25% or below, RES is output. Refer to the timing charts on the following pages for an explanation of the operation of the watchdog filter. Usage Notes • When the P-RUN frequency reaches 20 kHz or above, tOFF is short (see the timing charts on the following pages). This must be borne in mind in the design stage. • If the P-RUN frequency fluctuates, RES may also be output within the normal detection set frequency (see the timing charts on the following pages). • Detection frequencies fH and fL described in the Data Book are Typ values, and a certain amount of dispersion can be expected. A margin of ±30% or more should be allowed for in the design. 0.1 µ A VCC (5 V) CR Low voltage detection block Iw 0.8 µ typ CF Q 3.6 V I1 8 µ typ − + − + C RES 3.2 V 1.6 V 0.9 V − + 0.01 µ P-RUN DQ φQ Q 1/2 frequency divider WD B I2 10.7 µ typ Watchdog filter circuit Power-on and auto-reset circuit Figure 3 Watchdog Timer Evaliation Circuit Rev.3.00 Jun 15, 2005 page 7 of 30 HA16117F Series 1. When P-RUN signal is not input The watchdog filter circuit output (WD) is fixed low, so the RES signal is output as shown in the figure below in accordance with power-on and auto-reset circuit CR charge/discharge. H P-RUN L H Q L H Q L H A L 5V 3.6 V CF 0.9 V 0V H WD L 5V 3.2 V CR 1.6 V 0V H B L H C L H RES L 20 ms 60 ms Rev.3.00 Jun 15, 2005 page 8 of 30 HA16117F Series 2. With a low-frequency P-RUN signal (≈ 13 Hz to 26 Hz) When fP-RUN is 13 Hz to 26 Hz, the WD duty (D = 100 × t2/2T) is 25% to 50%. When the WD duty is 25% or above, multivibrator (power-on and auto-reset circuit) oscillation stops. As a result, the RES signal is fixed high. 40 ms (25 Hz) H P-RUN L H Q L H Q L H A L 5V 3.6 V CF 0.9 V 0V H WD L 5V t2 33 ms t1 5 µs 2T 3.2 V CR 1.6 V 0V H B L H C L H RES L 20 ms 60 ms Rev.3.00 Jun 15, 2005 page 9 of 30 HA16117F Series 3. With a 10 kHz P-RUN signal When fP-RUN is 10 kHz, the WD duty (D = 100 × (T − t2)/2T) is 48%. As the duty is above 25%, the multivibrator (power-on and auto-reset circuit) does not oscillate. The RES signal remains high. 100 µs (10 kHz) H P-RUN L H Q L H Q L H A L 5V 3.6 V CF 0.9 V 0V H WD L 5V t1 5 µs 2T 3.2 V CR 1.6 V 0V H B L H C L H RES L Rev.3.00 Jun 15, 2005 page 10 of 30 HA16117F Series 4. With a 150 kHz P-RUN signal When fP-RUN is 100 kHz or above, the WD duty (D = 100 × (T − t2)/2T) is 25% or below. Therefore, CR is discharged, and the RES signal is output at the instant that the pin potential falls to the comparator circuit threshold value (VTL = 1.6 V). 6.6 µs (150 kHz) H P-RUN L H Q L H Q L H A L 5V 3.6 V CF 0.9 V 0V H WD L 5V t1 5 µs 2T 3.2 V CR 1.6 V 0V H B L H C L H RES L Rev.3.00 Jun 15, 2005 page 11 of 30 HA16117F Series 5. tOFF when P-RUN signal ≈ 90 kHz When the P-RUN frequency is high, even though within specification, the CR pin potential falls. If the P-RUN frequency falls sharply at this time, tOFF may be short. With values of CF = 0.01 µF and CR = 0.1 µF, the CR pin potential will not fall as long as the P-RUN frequency is 20 kHz or below. H P-RUN L H Q L H Q L H A L 5V 3.6 V CF 0.9 V 0V H WD L 5V fP_RUN ≈ 90 kHz 50 ms 3.2 V CR 1.6 V ≈ 2.3 V 0V H B L H C L H RES L tOFF 26 ms Rev.3.00 Jun 15, 2005 page 12 of 30 HA16117F Series 6. When P-RUN frequency fluctuates (1) If there is a double-pulse in P-RUN, the WD filter duty will be decreased and RES will be output, as shown in the figure below, for example. In this case, the condition for non-output of the RES signal is a value of 3 or less for the ratio of P-RUN pulse interval minimum value to maximum value (when fP-RUN ≤ 20 kHz). This is because the CR pin charge/discharge current ratio is 3. 2 ms H P-RUN L H Q L H Q L H A L 5V 3.6 V CF 0.9 V 0V H WD L 5V 28 ms 3.2 V CR 1.6 V 0V H B L H C L H RES L 20 ms Rev.3.00 Jun 15, 2005 page 13 of 30 HA16117F Series 7. When P-RUN frequency fluctuates (2) If there is a double-pulse in P-RUN, RES will not be output as long as the ratio of P-RUN pulse interval minimum value to maximum value is 3 or less. The timing chart for a P-RUN minimum interval of 8 ms and maximum interval of 22 ms is shown below. 8 ms H P-RUN L H Q L H Q L H A L 5V 3.6 V CF 0.9 V 0V H WD L 5V 22 ms 3.2 V CR 1.6 V 0V H B L H C L H RES L Rev.3.00 Jun 15, 2005 page 14 of 30 HA16117F Series 8. Summary of cases where P-RUN frequency fluctuates If there is a double-pulse in P-RUN, RES may be output if the double-pulse has multiple frequency components. If the P-RUN frequency fluctuates, refer to the following when making the P-RUN setting. • P-RUN normal detection region, duty dependency 1M Note: 1 When fP-RUN ≥ 20 kHz, tOFF is frequency-dependent, so care is required when making the P-RUN setting (see figure below). 100 k P-RUN frequency fP-RUN (Hz) 10 k 1k Normal detection region*2 100 10 1 0 50 P-RUN pulse duty D (%) 100 Note: 2. This is the region when fP-RUN is constant. If fP-RUN fluctuates within the normal detection region, the following applies: Normal detection is performed when the condition fP-RUN H/fP-RUN L < M is satisfied. • fP-RUN dependency of VCR, tOFF, M 5 tOFF (s) 100 m 3 CR voltage VCR (V) 4 3 2 1 0 1k 3k 5 k 7 k 10 k P-RUN frequency (Hz) 30 k 50 k 70 k 100 k Multivibrator threshold voltage (1.6 V) 2M 50 m 0 1 Rev.3.00 Jun 15, 2005 page 15 of 30 HA16117F Series Setting of RES Timing and Watchdog Frequency Range Different MPUs have different RES timing requirements. The minimum reset time (tON) required at power-on (rise of VCC) is 20 ms for some MPUs and 100 ms for others. RES timing waveform parameters must be selected according to the MPU. With the HA16117F the timing of the RES output and the watchdog frequency range can both be set by external constants (CF, CR, and K). Parameters Item Power-on reset time Reset-clock off time Reset low time Reset high time Watchdog frequency high tON tOFF tRL tRH fH * 2 Symbol CR (pin 4) CF (pin 3) K (pin 8) * 1 Watchdog frequency low fL Notes: 1. K = R2 / (R1 + R2) 2. Variability of tOFF increases with increasing CF. The variability ∆tOFF is approximately 3.3 (MΩ) × CF (µF), so CF ≤ 0.01 (µF) is recommended. 3. External constants should be selected with reference to the formulas in tables 1 and 2. Table 1 tON (ms) tOFF (ms) tRL (ms) Calculation of RES Output Timing Item Formula 400 (Ω) × CR (µF) 1.99 × tRH (ms) 0.5 × tON (ms) 1.6 (V) × CR (µF) × 103 K × 31 (µA) − 15.8 (µA) ≈ tOFF (ms) Notes tON and tOFF can be set independently tRL and tRH can be set independently tRH (ms) tSL (ms) Table 2 fH (MHz) fL (Hz) Calculation of Watchdog Frequency Range Item Formula 1 tRH (ms) − tRL (ms) × 500 (Ω) × CF (µF) tRH (ms) + tRL (ms) 1 tRL (ms) × 1.7 (MΩ) × CF (µF) tRH (ms) + tRL (ms) Whichever is larger or 1 × 103 tOFF (ms) Rev.3.00 Jun 15, 2005 page 16 of 30 HA16117F Series Selection of External Constants If the reset duration necessary for the MPU to operate reliably at power-on is known, there is a simple procedure for selecting external constants, starting from the power-on reset time (tON). External constant Check watchdog values frequency range fH and fL START Set power-on reset time tON • Decide reset low time (tRL) • Select external constant CR Set reset high time tRH • Decide reset-clock off time (tOFF) • Select external constants R1 and R2 Select external constant CF Figure 4 Procedure for Selecting External Constants Application Example SW Battery 5V regulator VCC Tadj R1 510 kΩ R2 750 kΩ VCC Microprocessor system RES PORT GND CF 0.01 µF CR 0.1 µF P-RUN ACC HA16117F GND CF CR RES Rev.3.00 Jun 15, 2005 page 17 of 30 HA16117F Series Operating Characteristics and Test Circuits 510 k 5V 0V VCC Tadj 750 k P-RUN ACC 0V CF CR 5V RES 0V 50 ms/div Power-on reset time (tON) 5V 0V f = 500Hz duty 50% time tON 0.01 µ 0.1 µ Oscilloscope Circuit for measuring tON GND RES 5V VTL VCC 5V VCC 50½ CF CR GND RES Tadj 5V P-RUN 0V 5V RES 0V 50 ms/div 510 k SW,OFF 750 k P-RUN ACC tOFF 0.01 µ 0.1 µ Oscilloscope Circuit for measuring tOFF time Reset-clock off time (tOFF) tRH 5V RES VCC 5V Tadj 510 k 750 k P-RUN ACC CF GND RES CR 0.01 µ 0V tRL 20 ms/div time 0.1 µ CR Oscilloscope Oscilloscope Circuit for measuring RES and CR waveforms RES and CR waveforms at detect abnormal conditions Rev.3.00 Jun 15, 2005 page 18 of 30 HA16117F Series Low Voltage Threshold vs. Ambient Temperature 5.0 HA16117FA VTL -Ta 12 V 510 k VCC VCC Tadj 750 k 5V regulator Low voltage threshold VTL (V) 4.5 (−50ppm/°C) P-RUN ACC CF GND RES 4.0 0.01 µ 0.1 µ CR Oscilloscope 3.5 −30 0 50 85 Test circuit Ambient temperature Ta (°C) Threshold Hysteresis Width vs. Ambient Temperature 150 Threshold hysteresis width VHYS (mV) HA16117FA VHYS -Ta VCC VCC Tadj 12V 510k 100 P-RUN ACC CF CR GND RES 750k 5V regulator 50 0.01µ 0.1µ Oscilloscope 0 −30 0 50 85 Test circuit Ambient temperature Ta (°C) Rev.3.00 Jun 15, 2005 page 19 of 30 HA16117F Series Operating Supply Current vs. P-RUN Input Frequency 500 µ Ta = 25°C Operating supply current ICC (A) 100 µ 10 µ 100 1k P-RUN input frequency fP-RUN (Hz) 10 k 20 k A ICC 510 k VCC pin 5V Pulse genelator VCC 0 V to 5 V Tadj 750 k P-RUN ACC CF CR GND RES 0.01 µ 0.1 µ Test circuit Rev.3.00 Jun 15, 2005 page 20 of 30 HA16117F Series Standby Supply Current vs. Supply Voltage 200 µ Ta = 25°C A Standby supply current ISTBY (A) ISTBY VCC V VCC 100 µ Tadj 510 k 750 k P-RUN ACC 12 V CF CR 0.01 µ 0.1 µ GND RES Test circuit 0 5 Supply Voltage VCC (V) 7 Supply Current vs. Ambient Temperature 300 µ Supply current ISTBY, ICC (A) 200 µ f = 20 kHz ICC 100 µ f = 100 Hz ICC ISTBY 0 −30 0 50 85 Ambient temperature Ta (°C) Rev.3.00 Jun 15, 2005 page 21 of 30 HA16117F Series RES Low Voltage vs. RES pin Sink Current 0.4 51 k 75 k RES low voltage VOL (V) 0.3 5V VCC Tadj P-RUN ACC CF CR 0.2 (R O N 6 ≈1 0Ω ) GND RES 0.1 0.01 µ V Io sink Test circuit 0 0.5 m 1m 1.5 m RES pin sink current IOL (A) RES Low Voltage vs. Ambient Temperature 0.3 RES low voltage VOL (V) IOL = 1mA 0.2 0.1 0 −30 0 50 85 Ambient temperature Ta (°C) Rev.3.00 Jun 15, 2005 page 22 of 30 HA16117F Series RES High Voltage vs. RES pin Source Current 5 Ta = 25°C RES high voltage VOH (V) VCC 5V 4 0.01 µ 0.1 µ Tadj 51 k 75 k P-RUN ACC CF CR GND RES V Test circuit Io sink 3 0 500 µ RES pin source current Io source (A) Rev.3.00 Jun 15, 2005 page 23 of 30 HA16117F Series Power-on Reset Time vs. CR Capacitance 1 Ta = 25°C VCC Power-on reset time tON (sec) 5V 100 m Tadj 510 k 750 k P-RUN ACC CF CR GND RES 0.01 µ CR Oscilloscope 10 m VCC RES tON 1m 0.01 µ Test circuit 0.1 µ External capacitance CR (F) 1.0 µ RES Output Timing vs. CR Capacitance 1 Ta = 25°C 510 k 750 k RES output timing tRH, tRL (sec) VCC 100 m tRH 5V Tadj P-RUN ACC CF CR GND RES tRL 10 m 0.01 µ CR Oscilloscope tRH RES 5V 0V 1m 0.01 µ 0.1 µ External capacitance CR (F) 1.0 µ Test circuit Rev.3.00 Jun 15, 2005 page 24 of 30 HA16117F Series High Setup Time vs. CR Capacitance 1000 µ Ta = 25°C High setup time tSH (sec) 100 µ 5V VCC Tadj 510 k 750 k P-RUN ACC CF GND RES RES 0V 10 µ CR 0.01 µ CR tSH Oscilloscope 1µ 0.01 µ Test circuit 0.1 µ External Capacitance CR (F) 1.0 µ Low Setup Time vs. CR Capacitance 10 Ta = 25°C 5V VCC Tadj 510 k 750 k P-RUN ACC CF GND RES Low setup time tSL (sec) 1 0.01 µ CR CR Oscilloscope 100 m 15 V 0V RES 10 m 0.01 µ 0.1 µ 1.0 µ Test circuit tSL External Capacitance CR (F) Rev.3.00 Jun 15, 2005 page 25 of 30 HA16117F Series Reset High Time vs. K (Tadj Constant) 100 m Reset high time tRH (sec) VCC 5V Tadj R1 R2 P-RUN ACC CF CR GND RES 0.01 µ 10 m 0.56 0.6 0.7 Tadj constant K 0.8 0.1 µ Oscilloscope K= Test circuit R2 R1 + R2 Duty-cycle dependence of P-RUN normal frequency range 1M MPU system abnormal 100 k Abnormal if duty cycle is 0% 10 k Pulse generator MPU system normal Abnormal if duty cycle is 100% 5V 0V 0.01 µ 0.1 µ 5V VCC Tadj 510 R 750 R P-RUN input frequency fP-RUN (Hz) P-RUN ACC CF CR GND RES 1k 100 Oscilloscope 10 MPU system abnormal 1 0 50 100 P-RUN input pulse duty cycle (%) Test circuit Notes: 1. Normal detection is assumed when RES is not output. 2. The figure at left is for a constant P-RUN frequency. See "8. Summary of cases where P-RUN frequency fluctuates" for cases where the frequency fluctuates. Rev.3.00 Jun 15, 2005 page 26 of 30 HA16117F Series P-RUN Input Frequency vs. K (Tadj constant) 1M Ta = 25°C R2 R 1 + R2 Pulse generator 10 k 5V 0V duty 50% 1k MPU system normal 100 K= Test circuit 10 MPU system abnormal 1 0.55 0.6 0.7 Tadj constant K 0.8 Notes: 1. Normal detection is assumed when RES is not output. 2. The figure at left is for a constant P-RUN frequency. 0.01 µ 0.1 µ Oscilloscope R2 R 1 + R2 K= 100 k P-RUN input frequency fP-RUN (Hz) 5V VCC Tadj R1 R2 P-RUN ACC CF CR GND RES P-RUN High Threshold Frequency vs. CF Capacitance 10 M Ta = 25°C 510 k P-RUN high threshold frequency fH (Hz) VCC 5V MPU system abnormal 1M Pulse generator CF 100 k CR Oscilloscope 0 V to 5 V duty 50% CF CR GND RES Tadj 750 k P-RUN ACC MPU system normal Test circuit Notes: 1. Normal detection is assumed when RES is not output. 10 k 500 p 1000 p 2. The figure at left is for a constant P-RUN frequency. 0.01 µ 0.03 µ External capacitance CF (F) Rev.3.00 Jun 15, 2005 page 27 of 30 HA16117F Series P-RUN Low Threshold Frequency vs. CF Capacitance 1k Ta = 25°C 51 k 75 k P-RUN low threshold frequency fL (Hz) Normal 5V 100 CR = 0.01 µF VCC Tadj P-RUN ACC CF CR GND RES CR = 0.1 µF Abnormal 10 CR = 1.0 µF Pulse generator CF CR Oscilloscope Test circuit Notes: 1. Normal detection is assumed when RES is not output. 1 500 p 1000 p 0.01 µ 0.03 µ 2. The figure at left is for a constant P-RUN frequency. External Capacitance CF (F) P-RUN Input Frequency vs. Ambient Temperature 1M P-RUN abnormal P-RUN input frequency fP-RUN (Hz) 100 k 5V fH 10 k duty 50% 1k P-RUN normal Pulse generator VCC Tadj 510 k 750 k P-RUN ACC CF CR GND RES Oscilloscope 100 fL 0.01 µ 0.1 µ 10 P-RUN abnormal 1 −30 0 50 85 Test circuit Notes: 1. Normal detection is assumed when RES is not output. 2. The figure at left is for a constant P-RUN frequency. Ambient temperature Ta (°C) Rev.3.00 Jun 15, 2005 page 28 of 30 HA16117F Series Power-on Reset Time vs. Ambient Temperature Power-on reset time tON (ms) 100 VCC 5V Tadj 510 k 750 k P-RUN ACC CF GND RES 50 tON 0.01 µ CR CR Oscilloscope 0 −30 0 50 100 Ambient temperature Ta (°C) VCC RES Power-on Reset Time vs. Ambient Temperature tON Test circuit tRH and tRL vs. Ambient Temperature 100 VCC Tadj 51 k 75 k 70 tRH 5V P-RUN ACC CF CR GND RES tRH and tRL (ms) 50 0.01 µ 0.1 µ Oscilloscope 30 tRL 5V 0V tRH tRL 0 −35 0 50 85 Test circuit Ambient temperature Ta (°C) Rev.3.00 Jun 15, 2005 page 29 of 30 HA16117F Series Package Dimensions JEITA Package Code P-SOP8-4.4x4.85-1.27 RENESAS Code PRSP0008DE-A Previous Code FP-8D MASS[Typ.] 0.1g *1 D 5 F 8 NOTE) 1. DIMENSIONS"*1 (Nom)"AND"*2" DO NOT INCLUDE MOLD FLASH. 2. DIMENSION"*3"DOES NOT INCLUDE TRIM OFFSET. bp b1 HE c1 E *2 c Reference Symbol Dimension in Millimeters Min Nom 4.85 4.4 Max 5.25 Index mark Terminal cross section D E A2 A1 0.00 0.10 0.20 2.03 1 Z e 4 *3 A bp x M L1 bp b1 c c1 0.17 0.34 0.42 0.40 0.22 0.20 0° 6.35 6.50 1.27 0.50 0.27 θ A HE 8° 6.75 θ A1 L e x y 0.12 0.15 0.75 0.42 1 y Detail F Z L L 0.60 1.05 0.85 Rev.3.00 Jun 15, 2005 page 30 of 30 Sales Strategic Planning Div. Keep safety first in your circuit designs! Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan 1. Renesas Technology Corp. puts the maximum effort into making semiconductor products better and more reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may lead to personal injury, fire or property damage. Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of nonflammable material or (iii) prevention against any malfunction or mishap. Notes regarding these materials 1. These materials are intended as a reference to assist our customers in the selection of the Renesas Technology Corp. product best suited to the customer's application; they do not convey any license under any intellectual property rights, or any other rights, belonging to Renesas Technology Corp. or a third party. 2. Renesas Technology Corp. assumes no responsibility for any damage, or infringement of any third-party's rights, originating in the use of any product data, diagrams, charts, programs, algorithms, or circuit application examples contained in these materials. 3. All information contained in these materials, including product data, diagrams, charts, programs and algorithms represents information on products at the time of publication of these materials, and are subject to change by Renesas Technology Corp. without notice due to product improvements or other reasons. It is therefore recommended that customers contact Renesas Technology Corp. or an authorized Renesas Technology Corp. product distributor for the latest product information before purchasing a product listed herein. The information described here may contain technical inaccuracies or typographical errors. Renesas Technology Corp. assumes no responsibility for any damage, liability, or other loss rising from these inaccuracies or errors. Please also pay attention to information published by Renesas Technology Corp. by various means, including the Renesas Technology Corp. Semiconductor home page (http://www.renesas.com). 4. When using any or all of the information contained in these materials, including product data, diagrams, charts, programs, and algorithms, please be sure to evaluate all information as a total system before making a final decision on the applicability of the information and products. Renesas Technology Corp. assumes no responsibility for any damage, liability or other loss resulting from the information contained herein. 5. Renesas Technology Corp. semiconductors are not designed or manufactured for use in a device or system that is used under circumstances in which human life is potentially at stake. Please contact Renesas Technology Corp. or an authorized Renesas Technology Corp. product distributor when considering the use of a product contained herein for any specific purposes, such as apparatus or systems for transportation, vehicular, medical, aerospace, nuclear, or undersea repeater use. 6. The prior written approval of Renesas Technology Corp. is necessary to reprint or reproduce in whole or in part these materials. 7. If these products or technologies are subject to the Japanese export control restrictions, they must be exported under a license from the Japanese government and cannot be imported into a country other than the approved destination. Any diversion or reexport contrary to the export control laws and regulations of Japan and/or the country of destination is prohibited. 8. Please contact Renesas Technology Corp. for further details on these materials or the products contained therein. RENESAS SALES OFFICES Refer to "http://www.renesas.com/en/network" for the latest and detailed information. Renesas Technology America, Inc. 450 Holger Way, San Jose, CA 95134-1368, U.S.A Tel: (408) 382-7500, Fax: (408) 382-7501 Renesas Technology Europe Limited Dukes Meadow, Millboard Road, Bourne End, Buckinghamshire, SL8 5FH, U.K. Tel: (1628) 585-100, Fax: (1628) 585-900 Renesas Technology Hong Kong Ltd. 7th Floor, North Tower, World Finance Centre, Harbour City, 1 Canton Road, Tsimshatsui, Kowloon, Hong Kong Tel: 2265-6688, Fax: 2730-6071 Renesas Technology Taiwan Co., Ltd. 10th Floor, No.99, Fushing North Road, Taipei, Taiwan Tel: (2) 2715-2888, Fax: (2) 2713-2999 Renesas Technology (Shanghai) Co., Ltd. Unit2607 Ruijing Building, No.205 Maoming Road (S), Shanghai 200020, China Tel: (21) 6472-1001, Fax: (21) 6415-2952 Renesas Technology Singapore Pte. Ltd. 1 Harbour Front Avenue, #06-10, Keppel Bay Tower, Singapore 098632 Tel: 6213-0200, Fax: 6278-8001 http://www.renesas.com © 2005. Renesas Technology Corp., All rights reserved. Printed in Japan. Colophon 2.0