555 timer IC


Electronic symbol
NE555 from Signetics in dual-in-line package
Type	Active, Integrated circuit
Invented	Hans Camenzind
First production	1971
Pin configuration	GND, TRIG, OUT, RESET, CTRL, THR, DIS, VCC
Internal block diagram

The 555 timer IC is an integrated circuit (chip) used in a variety of timer, pulse generation, and oscillator applications. The 555 can be used to provide time delays, as an oscillator, and as a flip-flop element. Derivatives provide up to four timing circuits in one package.
Introduced in 1971 by American company Signetics, the 555 is still in widespread use due to its low price, ease of use, and stability. It is now made by many companies in the original bipolar and also in low-power CMOS types. As of 2003, it was estimated that 1 billion units are manufactured every year.^[1]

Design

Internal schematic (bipolar version)

Internal schematic (CMOS version)

The IC was designed in 1971 by Hans Camenzind under contract to Signetics, which was later acquired by Dutch company Philips Semiconductors (now NXP).
Depending on the manufacturer, the standard 555 package includes 25 transistors, 2 diodes and 15 resistors on a silicon chip installed in an 8-pin mini dual-in-line package (DIP-8).^[2] Variants available include the 556 (a 14-pin DIP combining two 555s on one chip), and the two 558 & 559s (both a 16-pin DIP combining four slightly modified 555s with DIS & THR connected internally, and TR is falling edge sensitive instead of level sensitive).
The NE555 parts were commercial temperature range, 0 °C to +70 °C, and the SE555 part number designated the military temperature range, −55 °C to +125 °C. These were available in both high-reliability metal can (T package) and inexpensive epoxy plastic (V package) packages. Thus the full part numbers were NE555V, NE555T, SE555V, and SE555T. It has been hypothesized that the 555 got its name from the three 5 kΩ resistors used within,^[3] but Hans Camenzind has stated that the number was arbitrary.^[1]
Low-power versions of the 555 are also available, such as the 7555 and CMOS TLC555.^[4] The 7555 is designed to cause less supply noise than the classic 555 and the manufacturer claims that it usually does not require a "control" capacitor and in many cases does not require a decoupling capacitor on the power supply. Those parts should generally be included, however, because noise produced by the timer or variation in power supply voltage might interfere with other parts of a circuit or influence its threshold voltages.

Pins

Pinout diagram

The connection of the pins for a DIP package is as follows:

Pin	Name	Purpose
1	GND	Ground reference voltage, low level (0 V)
2	TRIG	The OUT pin goes high and a timing interval starts when this input falls below 1/2 of CTRL voltage (which is typically 1/3 V_CC, CTRL being 2/3 V_CC by default if CTRL is left open).
3	OUT	This output is driven to approximately 1.7 V below +V_CC, or to GND.
4	RESET	A timing interval may be reset by driving this input to GND, but the timing does not begin again until RESET rises above approximately 0.7 volts. Overrides TRIG which overrides THR.
5	CTRL	Provides "control" access to the internal voltage divider (by default, 2/3 V_CC).
6	THR	The timing (OUT high) interval ends when the voltage at THR ("threshold") is greater than that at CTRL (2/3 V_CC if CTRL is open).
7	DIS	Open collector output which may discharge a capacitor between intervals. In phase with output.
8	V_CC	Positive supply voltage, which is usually between 3 and 15 V depending on the variation.

Pin 5 is also sometimes called the CONTROL VOLTAGE pin. By applying a voltage to the CONTROL VOLTAGE input one can alter the timing characteristics of the device. In most applications, the CONTROL VOLTAGE input is not used. It is usual to connect a 10 nF capacitor between pin 5 and 0 V to prevent interference. The CONTROL VOLTAGE input can be used to build an astable multivibrator with a frequency-modulated output.

Modes

The IC 555 has three operating modes:

Bistable mode or Schmitt trigger – the 555 can operate as a flip-flop, if the DIS pin is not connected and no capacitor is used. Uses include bounce-free latched switches.
Monostable mode – in this mode, the 555 functions as a "one-shot" pulse generator. Applications include timers, missing pulse detection, bouncefree switches, touch switches, frequency divider, capacitance measurement, pulse-width modulation (PWM) and so on.
Astable (free-running) mode – the 555 can operate as an electronic oscillator. Uses include LED and lamp flashers, pulse generation, logic clocks, tone generation, security alarms, pulse position modulation and so on. The 555 can be used as a simple ADC, converting an analog value to a pulse length (e.g., selecting a thermistor as timing resistor allows the use of the 555 in a temperature sensor and the period of the output pulse is determined by the temperature). The use of a microprocessor-based circuit can then convert the pulse period to temperature, linearize it and even provide calibration means.

Bistable

Schematic of a 555 in bistable mode

In bistable (also called Schmitt trigger) mode, the 555 timer acts as a basic flip-flop. The trigger and reset inputs (pins 2 and 4 respectively on a 555) are held high via pull-up resistors while the threshold input (pin 6) is simply floating. Thus configured, pulling the trigger momentarily to ground acts as a 'set' and transitions the output pin (pin 3) to Vcc (high state). Pulling the reset input to ground acts as a 'reset' and transitions the output pin to ground (low state). No timing capacitors are required in a bistable configuration. Pin 5 (control voltage) is connected to ground via a small-value capacitor (usually 0.01 to 0.1 μF). Pin 7 (discharge) is left floating.^[5]

Monostable

Astable

Schematic of a 555 in astable mode

In astable mode, the 555 timer puts out a continuous stream of rectangular pulses having a specified frequency. Resistor R₁ is connected between V_CC and the discharge pin (pin 7) and another resistor (R₂) is connected between the discharge pin (pin 7), and the trigger (pin 2) and threshold (pin 6) pins that share a common node. Hence the capacitor is charged through R₁ and R₂, and discharged only through R₂, since pin 7 has low impedance to ground during output low intervals of the cycle, therefore discharging the capacitor.
In the astable mode, the frequency of the pulse stream depends on the values of R₁, R₂ and C:

f = \frac{1}{\ln(2) \cdot C \cdot (R_1 + 2R_2)}

^[8]

The high time from each pulse is given by:

\mathrm{high} = \ln(2) \cdot C \cdot (R_1 + R_2)

and the low time from each pulse is given by:

\mathrm{low} = \ln(2) \cdot C \cdot R_2

where R₁ and R₂ are the values of the resistors in ohms and C is the value of the capacitor in farads.
The power capability of R₁ must be greater than

\frac{V_{cc}^{2}}{R_1}

.
Particularly with bipolar 555s, low values of

R_1

must be avoided so that the output stays saturated near zero volts during discharge, as assumed by the above equation. Otherwise the output low time will be greater than calculated above. The first cycle will take appreciably longer than the calculated time, as the capacitor must charge from 0V to 2/3 of V_CC from power-up, but only from 1/3 of V_CC to 2/3 of V_CC on subsequent cycles.
To have an output high time shorter than the low time (i.e., a duty cycle less than 50%) a small diode (that is fast enough for the application) can be placed in parallel with R₂, with the cathode on the capacitor side. This bypasses R₂ during the high part of the cycle so that the high interval depends only on R₁ and C, with an adjustment based the voltage drop across the diode. The voltage drop across the diode slows charging on the capacitor so that the high time is a longer than the expected and often-cited ln(2)*R₁C = 0.693 R₁C. The low time will be the same as above, 0.693 R₁C. With the bypass diode, the high time is

\mathrm{high} = R_1 \cdot C \cdot \ln\left(\frac{2V_{\textrm{cc}}-3V_{\textrm{diode}}}{V_{\textrm{cc}}-3V_{\textrm{diode}}}\right)

where V_diode is when the diode's "on" current is 1/2 of V_cc/R₁ which can be determined from its datasheet or by testing. As an extreme example, when V_cc= 5 and V_diode= 0.7, high time = 1.00 R₁C which is 45% longer than the "expected" 0.693 R₁C. At the other extreme, when V_cc= 15 and V_diode= 0.3, the high time = 0.725 R₁C which is closer to the expected 0.693 R₁C. The equation reduces to the expected 0.693 R₁C if V_diode= 0.
The operation of RESET in this mode is not well-defined. Some manufacturers' parts will hold the output state to what it was when RESET is taken low, others will send the output either high or low.
The astable configuration, with two resistors, cannot produce a 50% duty cycle. To produce a 50% duty cycle, eliminate R1, disconnect pin 7 and connect the supply end of R2 to pin 3, the output pin. This circuit is similar to using an inverter gate as an oscillator, but with fewer components than the astable configuration, and a much higher power output than a TTL or CMOS gate. The duty cycle for either the 555 or inverter-gate timer will not be precisely 50% due to the fact the timing network is supplied from the devices output pin, which has different internal resistances depending on whether it is in the high or low state (high side drivers tend to be more resistive).

Specifications

These specifications apply to the NE555. Other 555 timers can have different specifications depending on the grade (military, medical, etc.).

Supply voltage (V_CC)	4.5 to 15 V
Supply current (V_CC = +5 V)	3 to 6 mA
Supply current (V_CC = +15 V)	10 to 15 mA
Output current (maximum)	200 mA
Maximum Power dissipation	600 mW
Power consumption (minimum operating)	30 mW@5V, 225 mW@15V
Operating temperature	0 to 70 °C

Derivatives

Many pin-compatible variants, including CMOS versions, have been built by various companies. Bigger packages also exist with two or four timers on the same chip. The 555 is also known under the following type numbers:

Manufacturer	Model	Remark
Custom Silicon Solutions^[9]	CSS555/CSS555C	CMOS from 1.2 V, IDD < 5 µA
CEMI	ULY7855
ECG Philips	ECG955M
Exar	XR-555
Fairchild Semiconductor	NE555/KA555
GoldStar	GSC555	CMOS
Harris	HA555
Hitachi	HA17555
IK Semicon	ILC555	CMOS from 2 V
Intersil	SE555/NE555
Intersil	ICM7555	CMOS
Lithic Systems	LC555
Maxim	ICM7555	CMOS from 2 V
Motorola	MC1455/MC1555
National Semiconductor	LM1455/LM555/LM555C
National Semiconductor	LMC555	CMOS from 1.5 V
NTE Sylvania	NTE955M
Raytheon	RM555/RC555
RCA	CA555/CA555C
STMicroelectronics	NE555N/ K3T647
STMicroelectronics	TS555	CMOS from 2 V
Texas Instruments	SN52555/SN72555
Texas Instruments	TLC555	CMOS from 2 V
USSR	К1006ВИ1
X-REL Semiconductor	XTR655	Operation from -60°C to 250+°C
Zetex	ZSCT1555 (discontinued)	down to 0.9 V
NXP Semiconductors	ICM7555	CMOS
HFO / East Germany	B555

556 dual timer

Die of a 556 dual timer manufactured by STMicroelectronics.

The dual version is called 556. It features two complete 555s in a 14 pin DIL package.

558 quad timer

Die of a 558 quad timer.

The quad version is called 558 and has 16 pins. To fit four 555s into a 16 pin package the power, control voltage, and reset lines are shared by all four modules. Each module's discharge and threshold circuits are wired together internally.

Example applications

Joystick interface circuit using the 558 quad timer

The Apple II microcomputer used a quad timer 558 in monostable (or "one-shot") mode to interface up to four "game paddles" or two joysticks to the host computer. It also used a single 555 for flashing the display cursor.
A similar circuit was used in the IBM PC.^[10] In the joystick interface circuit of the IBM PC, the capacitor of the RC network (see Monostable Mode above) was generally a 10 nF capacitor. The resistor of the RC network consisted of the potentiometer inside the joystick along with an external resistor of 2.2 kΩ.^[11] The joystick potentiometer acted as a variable resistor. By moving the joystick, the resistance of the joystick increased from a small value up to about 100 kΩ. The joystick operated at 5 V.^[12]
Software running in the host computer started the process of determining the joystick position by writing to a special address (ISA bus I/O address 201h).^[12]^[13] This would result in a trigger signal to the quad timer, which would cause the capacitor of the RC network to begin charging and cause the quad timer to output a pulse. The width of the pulse was determined by how long it took the C to charge up to 2/3 of 5 V (or about 3.33 V), which was in turn determined by the joystick position.^[12]^[14] The software then measured the pulse width to determine the joystick position. A wide pulse represented the full-right joystick position, for example, while a narrow pulse represented the full-left joystick position.^[12]

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