TX4939XBG-400 Toshiba, TX4939XBG-400 Datasheet - Page 44

TX4939XBG-400

Manufacturer Part Number

TX4939XBG-400

Description

Manufacturer

Toshiba

Datasheet

1.TX4939XBG-400.pdf (740 pages)

Specifications of TX4939XBG-400

Cpu Core

TX49/H4 90nm

Clock Mhz/max Mips

400/520

Inst./data Cache

32KB (4 Way)/32KB (4 Way)

Tlb

1cycle Mac

Volts (v)

1.25/2.5/3.3

Peripherals

DDR, NAND, ATA, ETHERNET, SECURITY, FPU, MMU, SPI, I2S, I2C, PCI, VIDEO, UART, TIMER, RTC

Companion Chip

TC86C001FG

Package

PGBA456

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3.3.8

3.3.9

The failure rate of semiconductor devices is greatly increased as operating temperatures increase. As shown in

Figure 2, the internal thermal stress on a device is the sum of the ambient temperature and the temperature rise

due to power dissipation in the device. Therefore, to achieve optimum reliability, observe the following

precautions concerning thermal design:

(1) Keep the ambient temperature (Ta) as low as possible.

(2) If the device’s dynamic power dissipation is relatively large, select the most appropriate circuit board

(3) Derate the device’s absolute maximum ratings to minimize thermal stress from power dissipation.

When connecting inputs and outputs between devices, make sure input voltage (V

different supply voltages, such as in a dual-power-supply system, be aware that erroneous power-on and power-

off sequences can result in device breakdown. For details of how to interface particular devices, consult the

relevant technical datasheets and databooks. If you have any questions or doubts about interfacing, contact your

nearest Toshiba office or distributor.

Thermal design

material, and consider the use of heat sinks or of forced air cooling. Such measures will help lower the

thermal resistance of the package.

θja = θjc + θca

θja = (Tj–Ta) / P

θjc = (Tj–Tc) / P

θca = (Tc–Ta) / P

in which θja = thermal resistance between junction and surrounding air (°C/W)

Interfacing

) levels are matched. Otherwise, the devices may malfunction. When connecting devices operating at

θjc = thermal resistance between junction and package surface, or internal thermal

θca = thermal resistance between package surface and surrounding air, or external

Tj = junction temperature or chip temperature (°C)

Tc = package surface temperature or case temperature (°C)

Ta = ambient temperature (°C)

P = power dissipation (W)

resistance (°C/W)

thermal resistance (°C/W)

Figure 2 Thermal resistance of package

3 General Safety Precautions and Usage Considerations

θjc

θca

3-8

) and output voltage

TX4939XBG-400 Toshiba, TX4939XBG-400 Datasheet - Page 44

TX4939XBG-400

Specifications of TX4939XBG-400

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