Diagnostic Error Code

FRU/Action

 

 

 

015-034-XXX

1.

Reboot the system

USB port buffer

2.

Flash the system and re-test. See “Flash

allocation failure

 

update procedures” on page 150

 

 

 

3.

Run memory test

 

4.

System board

 

 

 

015-035-XXX

1.

Remove USB device(s) and re-test

USB port Reset condition detected

2.

System board

 

 

 

015-036-XXX

System board

USB port Register error

 

 

 

 

 

015-040-XXX

1.

Run setup and check for conflicts

USB port IRQ failure

2.

Flash the system. See “Flash update

 

 

 

procedures” on page 150

 

3.

System board

 

 

015-195-XXX

Information only

USB port Test aborted by user

Re-start the test, if necessary

 

 

 

015-196-XXX

1.

Press F3 to review the log file

USB port test halt, error threshold exceeded

2.

Re-start the test to reset the log file

 

 

 

 

015-197-XXX

1.

Make sure the component that is called

USB port test warning

 

out is connected and/or enabled. See

 

 

 

 

Chapter 6, “Using the Setup Utility,” on

 

 

page 53

 

2.

Re-run test

 

3.

Replace the component that is called out

 

 

in warning statement

 

4.

Replace the component under test

 

 

 

015-198-XXX

1.

If a component is called out, make sure

USB port test aborted

 

it is connected and/or enabled. See

 

 

 

 

Chapter 6, “Using the Setup Utility,” on

 

 

page 53

 

2.

Flash the system and re-test. See “Flash

 

 

update procedures” on page 150

 

3.

Go to “Undetermined problems” on page

 

 

88

 

 

 

015-199-XXX

1.

Go to “Undetermined problems” on page

USB port test failed, cause unknown

 

88

 

 

 

2.

Flash the system and re-test. See “Flash

 

 

update procedures” on page 150

 

3.

Replace component under function test

 

 

018-000-XXX

No action

PCI Card Test Passed

 

 

 

 

 

018-0XX-XXX

1.

Riser card, if installed

PCI Card Failure

2.

System board

 

 

 

 

018-195-XXX

1.

PCI card

PCI Card Test aborted by user

2.

Information only

 

 

 

Re-start the test, if necessary

 

 

 

68Hardware Maintenance Manual

Page 74
Image 74
Lenovo 8088, 8094 XXX Remove USB devices and re-test, XXX System board, XXX Run setup and check for conflicts, 015-199-XXX

8089, 8086, 8087, 8090, 8094 specifications

The Lenovo 8088, 8094, 8090, 8087, and 8086 series represent a significant portion of the historical legacy of computing, particularly in the realm of personal computers and microprocessors. Each of these models showcases unique features and technologies that contributed to the evolution of computing during their time.

Starting with the Lenovo 8088, this microprocessor was an enhancement of the earlier Intel 8086, designed primarily for use in IBM-compatible PCs. Its 16-bit processor architecture was notably capable of handling 8-bit data bus interactions, which made it more versatile for various applications. The 8088 had a maximum clock speed of 4.77 MHz, providing sufficient computational power for its time. One of the key features was its support for segmented memory, which allowed for more efficient memory management by dividing memory into segments for code, data, and stack.

The Lenovo 8094, while less commonly mentioned, often refers to IBM’s PS/2 line that utilized advanced features for the time. It supported VGA graphics, a significant improvement in visual output that opened new possibilities for graphical user interfaces. The 8094 also hosted a more sophisticated input/output system that allowed for better compatibility and connectivity with peripherals.

Moving to the Lenovo 8090, this model was part of the PS/2 portfolio, noted for its improved hardware architecture. It provided an upgraded interface for keyboard and mouse, which enhanced user interaction. With further support for high-density floppy disks and better memory access speeds, the 8090 paved the way for more efficient personal computing experiences.

The Lenovo 8087 was an auxiliary processor that brought floating-point arithmetic capabilities to the 8086 series. This coprocessor greatly expanded the computing power of the CPU by handling complex mathematical computations, which was especially useful in engineering and scientific applications. The 8087 allowed for more precise calculations than the basic integer math natively supported by earlier processors.

Finally, the Lenovo 8086, iconic in its own right, was a groundbreaking microprocessor that introduced the x86 architecture. It operated at clock speeds ranging from 5 to 10 MHz and was one of the first to support 16-bit data types fully. Its capabilities shaped software development and computer programming and established a foundation for the PC compatibles we know today.

In summary, the evolution from the Lenovo 8088 through to the 8086 helped shape modern computing paradigms by introducing features that improved performance, efficiency, and user experience, paving the way for the vast technological advancements seen in contemporary computing devices.