Note: Not all vehicle entertainment systems offer a stereo auxiliary audio input. In some cases, if your system does not support this input, one may be created using an adapter from a third-party vendor.

1Connect an RCA cable (not supplied) to connector E on the ISO cable.

2Connect the other connectors on the RCA cable to the vehicle entertainment system’s Auxiliary input.

3From the Installer menu, set the Line Out parameter to ON (see “Set install preferences” on page 11 for details).

Set install preferences

1Turn off your vehicle’s ignition.

2Turn on your vehicle’s ignition while pressing and holding the Green button for at least 5 seconds.

Installer Menu

Note: See page 13 for location of buttons and knobs on UIM.

3Use the scroll knob to view and change settings.

Setting...

Language

set language displayed on the UIM.

Display

set the display orientation for left- or

Orientation

right-hand operation.

 

 

Line Out

set to ON when using an auxiliary

 

input to your vehicle entertainment

 

system for music.

 

 

Privacy Mute

set whether to unmute the vehicle

 

entertainment system when a call is

 

switched to privacy mode.

 

 

Install Test

test and verify:

 

ignition source

 

left-side speakers

 

right-side speakers

 

auxiliary input to vehicle

 

entertainment system (if used).

 

 

Factory

reset all settings back to standard

Reset

default factory settings

 

 

About

list car kit’s software version

4Turn vehicle’s ignition off and on to store settings.

Installation 11

Page 13
Image 13
Motorola 68014301013, TK30 manual Set install preferences, Turn off your vehicle’s ignition

TK30, 68014301013 specifications

The Motorola 68014301013, also known as the TK30, represents a remarkable piece of technology in the realm of computing microprocessors. This chip, launched during an era of rapid technological advancement in the 1980s, was instrumental in the development of powerful and efficient computing systems, redefining performance metrics in its time.

One of the key features of the TK30 is its compatibility with the Motorola 68000 architecture, which was renowned for its thorough instruction set and operational efficiency. The TK30 extends this legacy, providing enhanced processing capabilities and improved instructions for complex computations. This compatibility allowed software developed for earlier Motorola processors to run seamlessly on the TK30, giving it an edge in versatility.

The TK30 boasts a 32-bit data bus and a 24-bit address bus, facilitating access to a significantly larger memory space, which is crucial for running advanced applications and managing more substantial datasets. This expanded memory capability was particularly beneficial for developers looking to create sophisticated software solutions or for companies looking to improve their computing power without overhauling their existing systems.

Another remarkable characteristic of the TK30 is its support for multitasking. As the demands for processor efficiency grew, the TK30 was designed to handle multiple operations simultaneously, allowing for smoother and faster execution of applications. This multitasking capability made it a preferred choice for various operating systems, further broadening its appeal in the computing market.

Power management is also a critical aspect of the TK30’s design. The processor employs advanced power-saving features, which help in reducing overall energy consumption, making it a suitable option for embedded systems where power usage is a crucial concern. This focus on energy efficiency aligns with contemporary demands for sustainability and longevity in electronic products.

In summary, the Motorola 68014301013, or TK30, is not merely a microprocessor; it is a versatile, powerful technology that has stood the test of time. With its robust compatibility with legacy systems, impressive memory capabilities, multitasking support, and energy efficiency, the TK30 continues to be relevant in discussions of historical computing innovations, symbolizing an era where microprocessor technology began to pivot towards the complexities of modern computing. Its influence can still be felt as the foundations it laid helped shape the trajectory of future processor designs and computing technologies.