UJA1075TW/5V0/WD,1 NXP Semiconductors, UJA1075TW/5V0/WD,1 Datasheet - Page 22

UJA1075TW/5V0/WD,1

Manufacturer Part Number

UJA1075TW/5V0/WD,1

Description

IC SBC CAN/LIN HS 5V 32HTSSOP

Manufacturer

NXP Semiconductors

Datasheet

1.UJA1075TW5V0118.pdf (53 pages)

Specifications of UJA1075TW/5V0/WD,1

Controller Type

System Basis Chip

Interface

CAN, LIN

Voltage - Supply

4.5 V ~ 28 V

Current - Supply

83µA

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

32-TSSOP Exposed Pad, 32-eTSSOP, 32-HTSSOP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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UJA1075_2

Product data sheet

6.7.1.1 Active mode

6.6.3 Voltage regulator V2

6.7.1 CAN operating modes

6.7 CAN transceiver

For short-circuit protection, a resistor needs to be connected between pins V1 and

VEXCC to allow the current to be monitored. This resistor limits the current delivered by

the external transistor. If the voltage difference between pins VEXCC and V1 reaches

not increase further.

The thermal performance of the transistor needs to be considered when calculating the

value of this resistor. A 3.3 Ω resistor was used with the BCP52-16 (NXP Semiconductors)

employed during testing. Note that the selection of the transistor is not critical. In general,

any PNP transistor with a current amplification factor (β) of between 60 and 500 can be

used.

If an external PNP transistor is not used, pin VEXCC must be connected to V1 while pin

VEXCTRL can be left open.

One advantage of this scalable voltage regulator concept is that there are no PCB layout

restrictions when using the external PNP. The distance between the UJA1075 and the

external PNP doesn’t affect the stability of the regulator loop because the loop is realized

within the UJA1075. Therefore, it is recommended that the distance between the

UJA1075 and PNP transistor be maximized for optimal thermal distribution.

The output voltage on V1 is monitored continuously and a system reset signal is

generated if an undervoltage event occurs. A system reset is generated if the voltage on

V1 falls below the undervoltage detection voltage (V

threshold (90 % or 70 % of the nominal value) is set via the Reset Threshold Control bit

(RTHC) in the Int_Control register

interrupt) will be generated at 90 % of the nominal output voltage. The status of V1 can be

read via bit V1S in the WD_and_Status register

Voltage regulator V2 is reserved for the high-speed CAN transceiver, providing a 5 V

supply.

V2 can be activated and deactivated via the MC bits in the Mode_Control register

(Table

voltage drops below 90 % of its nominal value. The status of V2 can be read via bit V2S in

the WD_and_Status register

V2 can be deactivated (MC = 10) to allow the internal CAN transceiver to be supplied from

an external source or from V1. The alternative voltage source must be connected to pin

V2. All internal functions (e.g. undervoltage protection) will work normally.

The analog section of the UJA1075 CAN transceiver corresponds to that integrated into

the TJA1042/TJA1043. The transceiver is designed for high-speed (up to 1 Mbit/s) CAN

applications in the automotive industry, providing differential transmit and receive

capability to a CAN protocol controller.

The CAN transceiver is in Active mode when:

th(act)Ilim

5). An undervoltage warning (a V2UI interrupt) is generated when the output

, the PNP current limiting activation threshold voltage, the transistor current will

All information provided in this document is subject to legal disclaimers.

Rev. 02 — 27 May 2010

(Table

4) in Normal mode (V2S = 1 in all other modes).

6). In addition, an undervoltage warning (a V1UI

High-speed CAN/LIN core system basis chip

(Table

uvd

; see

4).

Table

10). The reset

UJA1075

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UJA1075TW/5V0/WD,1 NXP Semiconductors, UJA1075TW/5V0/WD,1 Datasheet - Page 22

UJA1075TW/5V0/WD,1

Specifications of UJA1075TW/5V0/WD,1

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