IP-CAM

Posted in Application

Demand

Why needs ESD protection?

Why needs ESD protection for security devices? The security devices could be assembled in outdoor or indoor. In indoor, the devices are not usually damaged by surge directly, but it needs to consider the damage of over voltage. In outdoor, the devices must do protection to prevent direct lightning strike and avoid the lightning strike the equipment through lines. Therefore, to add proper overvoltage protection on each line in front of devices is necessary.

Standard

ESD: IEC61000-4-2
Surge: IEC61000-4-5

Solution

MLE Series
SHN Series
SHC Series
ULC Series
TVS Series
GDT Series

Application

IP CAM/Surveillance Interface MLE SHN SHC ULC TVS GDT
  Lens V          
Transmission RJ45   V     V  
Controller RS485/RS232         V V
Alarm system Alarm I/O   V        
Storage USB.HDMI V     V    
System Power Supply AC/DC/PoE   V V      

How to Select Models

To determine the test criteria:

  • Whether the voltage of power supply circuit is less than or equal to working voltage of varistor.
  • To verify if the leakage current will cause the heat or other effects in normal working voltage conditions.
  • To calculate the maximum transmission speed of the circuit and understand what kind of capacitor is suitable.
  • Surge test voltage and waveform.

Recommended Application

1. The surge waveform of system products:

  1. 1.2/50us waveform surge: the analog waveform caused by lightning goes through indoor lines and used to test of equipment for withstanding overvoltage levels test. The main test areas: power line of communications equipment and signal line of indoor buildings.
  2. 1.2/50us (8/20us) combination waveform: the surge generator output a waveform with specific open / short features. The generator output open-circuit and the waveform is 1.2/50us open-circuit condition. The generator output short-circuit and the waveform is 8/20us the short-circuit condition. This feature of the surge generator is mainly used for the device of withstanding overvoltage level test. The main test areas: power lines of communication equipment and the signal lines of inside building.
  3. 10/700us surge waveform: the analog waveform caused by lightning goes through outdoor lines. It’s used for the device of withstanding overvoltage level test. The main test area: the signal lines of outside building.
  4. 8/20us pulse waveform: the analog waveform caused by lightning goes through cables. It’s used for the device of withstanding overvoltage level test. The main test area: power port, signal port, and antenna port for communications equipment.

2. ESD protection design starts from PCB

Speaking of static protection design, the ESD protection must begin from the printed circuit board (PCB). On PCB, there are three situations to cause ESD mistakes as follows:
  1. The ESD direct current cause the pin of components permanent damage: This ESD surge current occurs by external parts (such as a keyboard, or I/O connectors). To prevent this direct damage, using a series resistor or capacitors in parallel can limit ESD current through IC.
  2. ESD current flowing through the circuit resulting in reset or damaged: most of the designers assume that ground circuit is low impedance, after ESD pulse, the impedance of the IC ground is very prone to ground bounce, this ground bounce will make IC reset or locked, such as locked, the IC is very easy to be destroyed by power.
  3. Indirect coupling of the electromagnetic field: such as the discharge of the vertical plate and horizontal plate, it makes the circuit reset. For the report of high-impedance components damaged, this failure mode is depends on PCB loop circuit area and whether construction shielding is good or not. For the protection of ESD, it can proceed from the construction shielding and PCB layout design.

3. ESD protection used on the PCB design technology

  1. The PCB layout arranged and discharge gap, which is acute triangle, copper foil tip, interval 6-10 mil approximately and one end connect to the earth.
  2. PCB layout must be considered to reduce the sensitivity of the electromagnetic field coupling. Using lots of anti-coupling capacitors can reduce the circuit area. Anti-coupling capacitors should be selected high voltage ceramic capacitors and these capacitors must be put close to the I/O connectors. High voltage ceramic capacitors put on the VCC and ground near PCB connector, which not only reduces the loop area, also with function of decoupling. Besides, the high resonant frequency by-pass capacitors between power and ground can reduce the reaction of indirect coupling of the induction field strength and electromagnetic fields, but the capacitor equivalent series inductance (ESL) and equivalent series resistors as low as possible.
  3. The PCB layout can use low-pass filter to release the ESD energy. The low-pass filter is combination of capacitors and inductors, which can prevent the high frequency ESD energy into the system. The inductors will present high impedance for surge, and thus reduce the energy intruded into system. The capacitor is put at the input of inductor will lead the ESD high frequency spectrum bypass to the ground.
  4. On PCB, it can utilize the clamping circuit to suppress the transient high voltage, such as transient voltage suppressor diodes. It must choose the specification of diodes which can withstand a few kV voltage and quick response dv / dt pulse and consume high-current
  5. In PCB layout design, the component which is sensitive in ESD can be isolated with other area by trenches method, in order to prevent the transfer of the ESD or coupling to other parts.
  6. For the electromagnetic coupling of indirect discharge and the arcing effect, adopting the multilayer board can enhance the protection for more than 10 times, compared to a single-layer board.

Others

In actual test, many manufacturers release the clamping voltage determined by a rise time 8μs and a rise continuing 20μs pulse. Most of the clamping voltage information shown in product datasheet is applied to the device at 1A pulse and sometimes will apply to a higher pulse current. This pulse can obtain repeatedly and easy to measure and thus it is widely used. Unfortunately, this pulse does not mean ESD pulse. The ESD pulse only has 1ns rise time, duration 60ns. In addition, the IEC 61000-4-2 level 4, the clamping voltage is very different between peak current 30A and 1A pulse.

To adopt standard 1A pulse, the clamping voltage of most semiconductor ESD protection diodes usually mark 8 ~ 15V. But, the clamping voltage will reach 50 ~ 100V at 8kV IEC 61000-4-2 test. This is determined by other characteristics of diodes, such as the dynamic resistance.

Some ESD manufacturers also provide ESD pulse waveform, but it is easy to be misunderstood. For example, manufacturers often use the attenuator to protect the test equipment from damage. However, the waveforms in the datasheet will not show the impact of attenuator. There will be 5 to 10 times tolerance existed for clamping voltage.